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HSD-TR-84-002 -_
AD-A202 525
A SURVEY AND EVALUATION OF CHEMICAL WARFARE
AGENT-DECONTAMINANTS AND DECONTAMINATION
15 OCTOBER 1984
Prepared by: Dr. Ming-houng (Albert) ChangDr. Alex CieglerDr. Roy Crochet
DTIC98(., U Computer Sciences Corporation
Engnering LaboratoryD -b .National Space Technvology Laboratories
D NSTL, Misissippi 39529
for
Aeromedlcal/Casualty System Program OfficeAerospace Medical DlvklgonDepartment of the Air Force
Brooks Air Force Base, Texas 78235
'4 °
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11 TTILnclude x a cri •a uc oni o nemical warfare 64703F 2866eurvcontaminants and econtaminatlon
12. PERSONAL AUTHOR(S)
Dr Ming-houng (Albert) Chang; Dr Alex Ciegler; Dr Roy Crochet13&. TYPE OF REPORT 13b. TIME COvEnFD 14. DATE OF REPORT iYr. Mo., L)ay) 15. PAGE COUNT
Survey & Eval.uation FROM To 1984 Oct 15 7516. SUPPLEMENTARY NOTATION
17 COSATI CODES 1 SUBJECT TERMS (Continue on reuerse if necetmar and identify by blocki number)
FIELD GROUP SUB. GR
15 06 06.03 Decontamination
99. A^ TRACT (Continue on ,wvere if neceuar'y anid iden (if> b) blocit numberl
--his report investigates methods of removing war casualties from their contaminatedprotective clothing without passing chemicals into the medical treatment areas. Nosingle decontamination method was found suitable, but four methods were identified forfurther investigation:
1. Application of Fuller's Earth mixed with Dutch powder.2. Application of a fast-setting polymer to~he protective gear.3. Application of a detoxicant chemical. I4. Application of cryptand and potassium acetate i 1 exane solution.
I I I ' t i\
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Maj MKlvin Murrav (512) 536-ZG75 1ISD/YAI
DD FORM 1473, 83 APR EDITION OF I JAN 73 IS OBSOLETE
SECURITY CLASSIFICATION OF THIS PAGE
PREFACE
The USAF Aeromedical Division (AMD) has tasked Computer Sciences
Corporation's Engineering Laboratory (CSC-EL) at the National Space Technology
Ldbordtories •NiL, in Bay St. Louis, Mississippi to design, fabricate, and
test prototype Contamination Control Areas (CCA's) to interface with Mobile
Collective Protection System-Medical (MCPS-M). This task consists of the
following three phases:
1. Decontamination alternative evaluation and system design
2. Functional mock-up fabrication, testing, and evaluation
3. Engineering model fabrication, testing, and evaluation.
This report, constituting deliverable items under phase one of the
contract, is concerned with a literature search, evaluation, and initial
selection of detoxicant and decontaminant systems. Also discussed will be
methods of d-.ontaminant application and selection of simulants.
Accesiu'r For
NTIS CR;&iOTIC TAjj
, ,!/ 0 -
I -I --
CONTENTS
PREFACE ................................................................... i
1. INTRODUCTION ......................................................... 1
2. OBJECTIVE .............................................. .............. 2
3. APPROACH ............................................................. 3
4. MILITARY PROTECTIVE GEAR ..................................... ...... 4
4.1 The Mdsk ........................................................ 5
4.2 The Hood ........................................................ 5
4.3 The Clothing .................................................... 5
4.4 The Gloves ...................................................... 9
4.5 The Overboots ................................................... 9
5. AGENT BEHAVIOR ON PROTECTIVE GEAR AND ITS RELATION TO DECONTAMINATION 9
6. LITERATURE REVIEW .................................................... 13
6.1 Physical Methods ................................................ 13
6.1.1 Sorbents ................................................. 146.1.2 Containment Materials .................................... 15
6.2 Biologial Methods ............................................... 16
6.3 Chemical Methods ................................................ 1/
6.3.1 Water/Solvent or Detergent Wash .......................... 176.3.2 Oxidation ................................................ 186.3.3 Hydrolysis ............................................... 24
7. CURRENT STANDARD DECONTAMINANTS USED IN THE U.S. ARMY ................ 31
7.1 Physical Procedures ............................................. 31
7.2 Chemical Procedures ............................................. 31
8. INDUSTRY SURVEY FOR AGEN1 DECONTAMINATION ............................ 33
8.1 Rohm and Hass Company (Spring House, Pennsylvania) .............. 33
8.2 H. 5. Fuller Coipany (St. Pau;, .innesota) ...................... 35
8.3 Chemical Coating and Engineering Corporation
(Media, Pennsylvania) ........................................... 35
8.4 3M Company (St. Paul, Minnesota) ................. .............. 36
8.5 Lab Safety Supply Company (Janesville, Wisconsin) ............... 36
9. EVALUATION AND ANALYSIS .............................................. 36
9.1 Sorbents ........................................................ 38
9.2 Containment Materials ........................................... 38
9.3 Water/Organic Solvents .......................................... 39
9.4 Oxidative Chemicals ............................................. 39
9.5 Hydrolytic Chemicals ............................................ 40
i0. DECONTAMINANT APPLICATION ............................................ 46
11. SIMULANTS ............................................................ 46
12. CONCLUSION AND RECOMMENDATIONS ...................................... 48
REFERENCES ................................................................ 49
APPENDIX A--REFERENCE SYNOPSES ............................................ 51
APPENDIX B--INDUSTRY TELEPHONE INQUIRIES .................................. 74
TABLES
1. Allowable Agant Levels ............................................... 2
2. U. S. Army Standard Chemical Decontaminants .......................... 32
3. The Most Effective Decontaminants in Each Feasibility Category ....... 37
4. Potential Decontaminants and Their Commercial Availability ........... 41
5. Agents and Their Corresponding Simulants ............................. 47
FIGURES
1. CBR ProtecLive Field Mask, ABC-Mi7 and Hood, ABC-M6A2 ................ 6
2. M6A2 Protective Field Hood ........................................... 7
3. Chemical Protective Suit (Overgarment) ............................... 8
iii
4. Chemical Protective Glove Set ........................................ 10
5. Footwear Cover, Chemical Protective (Overboots) ...................... 11
6. A Specially Designed Valve For Replacement of the Mask Filter ........ 43
7. Protective Clothing Cutting Lines .................................... 45
iv
A SURVEY AND EVALUATION OF CHEMICAL WARFARE
AGENT-DECONTAMINANTS AND DECONTAMINATION
1. INTRODUCTION
The AMD has identified the need for mobile Medical Contamination
Controi Areas (MCCA's) for the Second Echelon Medical System (SEMS) where
wounded personnel can enter for medical treatment. Before entering a Toxic
Free Area (TFA), casualties must be thoroughly decontaminated. Although the
present concept for an MCCA has been generally accepted, more development and
refinement are needed in the areas of decontamination and processing, because
current decontamination methodologies are too cumbersome, time consuming, and
inefficient.
The purpose of this report is two-fold:
a. To review literature and investigate new decontamination
technologies, which will lead to identifying more effective
detoxicants and decontaminant systems
b. Selection and development of more promising application methods
for decontamination processes which will meet the following AMD
decontamination criteria:
* Protective clothing should be decontaminated to below the
allowable levels, which will result in "no effect" levels
on skin as indicated in table 1. Allowable dosages
received by personnel are also listed.
* The decontamination process must be completed within four
minutes.
* Ability to remove or mask the reaction mixtures and agent
residues, while maintaining the integrity of the equipment
and MCCA.
TABLE 1. ALLOWABLE AGENT LEVELS
Maximum Liquid Maximum DosagesRemaining on Received by
Skin of Casualty PersonnelAgent (mg) (mg min/m
GB 0.003 0.05GD 0.003 0.01HD 0.02 0.2VX 0.003 0.002
0 The decontamination reaction and end-product will be
relatively non-toxic.
* The decontamination process will cause no harm or present
health hazards to involved personnel.
* A single decontaminating system will be used for all agents
and situations.
* An acceptable stoichiometry and logistics will be developed
(i.e., relatively small amount of decontaminant to be
effective for decontaminating agents).
* The detoxicant/decontaminant will be readily available and
easily applied at a reasonable cost.
6 Chemicals utilized will have a minimum storage life of
10 years.
2. OBJECTIVE
The overall objective of this contract is to develop methodology for
safely removing casualties from their contaminated protective clothing for
medical treatment. Therefore, the developed decontamination process must be
adequate, not only to detoxify agents, but also to prevent agent vapor
2
desorption from contaminated clothing. In addition, the decontamindtion
process must not damage the integrity of the MCCA system and must b7 effective
against any agent.
3. APPROACH
Ideally, decontaminants will effectively destroy, neutralize, remove,
or irreversibly bind the various agents in vapor, aerosol, liquid droplet, and
thickened form. Although numerous attempts have been made in the past
60 years to develop an ideal decontaminat;on process for chemical agents,
there seems to be no practical system available to meet ADM's decontamination
criteria listed in the introduction of this report. For this reason, con-
siderable effort was expended in an attempt to find new concepts to meet the
objectives of this contract. These new concepts, when applied alone or
combined with promising decontaminants, should quickly and completely decon-
taminate litter casualities.
One of these new concepts involves coating casualties who are still
in Mission-Oriented Protective Posture (MOPP)-level 4 gear, with a thin layer
of a fast-setting polymeric film or other binding and containment material
following mechanical application of a detoxicant/decontaminant. The polymeric
film is intended to completely seal residual agent or end-reaction products of
the agent and detoxicant onto the clothes. The advantages of this type of
"cocoon" coating are multiple:
a The coating should seal both unreacted agents and chemical
residues.
0 The coating should prevent desorption of absorbed agents.
Shortly after polymer application, the protective clothing can be cut away by
electric scissors and the casualty removed safely for medical assistance; thu
removed protective gear can then be disposed of immediately.
The data and information in this report were collected in two ways.
An extensive literature search was conducted to identify and evaluate all
3
previously known agents-decontaminants, fast-setting polymers, or binding, and
containment materials; telephone inquires were made to industries concerning
decontamination technologies. Decontamination approaches investigated include
removal, detoxification, inactivation, and suppression. The following data
bases and sub-bases were searched:
0 NASA/RECON (1968-1984)
* Lockheed DIALOG
AGRICOLA (1970-1984)
BIOSIS PREV. (1969-1984)
CHEMICAL ABSTRACTS (1968-1984)
CHEMICAL INDUSTRY NOTES (1974-1984)
ENVIROLINE (1971-1984)
EXCERPTA MEDICA (1975-1984)
FEDERAL RESEARCH PROGRAM (1982-1984)
FOOD SCIENCES AND TECHNOLOGY (1969-1984)
NTIS (1964-1984)
* DTIC (1918-1984)
After completing the computer literature information search, hundreds of
abstracts were obtained and reviewed. Complete copies of particularly rel-
evant publications gleaned from the abstracts were obtained for more detailed
study. A list of the title, author, date of publication, AD number, and a
synopsis of each selected article is appended to this report (Appendix A).
The telephone inquires with pertinent information have also been appended
(Appendix B).
4. MILITARY PROTECTIVE GEAR
The military protective gear includes mask, hood, clothing, gloves,
and overboots. A diagram of a typical protective gear is presented in
figures 1 to 5. Knowledge of the characteristics of this gear is essential if
proper detoxification/decontamination procedures are to be developed.
Therefore, each subitem of the protective gear will be described in detail in
the following subsections.
4
4.1 The Mask.
The mask provides protection for the user's face, eyes, and
respiratory tract from vapor and aerosol agents. The major components of the
mask are the face piece (9nerally known as the msk), eyelens outserts, a
voicemitter with a rubber cover, and one or two filters (depending on the
model). When the mask is worn, the filter material contained within the
filtr" elements remove agents frcm the ambient air. The decontaminated air
then -.,asses into the mask and is inhaled by the user. Exhaled air is
discharged through an outlet valve located at the chin position. The mask is
designed to effectively protezt the user from agents, but it does not protect
against ammonia vapor and carbon monoxide. The mask is made of natural rubber
with rigid and clear plastic eyelenses as shown in figure 1 (1).
4.2 The Hood.
The hood is used to cover and protect the user's head and neck. The
hood is made of butyl rubber and shown in figure 2.
4.3 The Clothing.
The clothing (shown in figure 3) is a two-piece suit consisting of a
coat and a pair of trousers. The coat has a short standing collar and a
full-length zippered opening covered by a double protective flap, elastic
sleeve closures, and two outer pockets located at chest level. The trousers
have two pockets, a fly-front with protective flap, adjustable waist tabs,
suspenders and belt loops, and zippers located on the lower outside section of
each leg. The clothing material consists of an outer layer of nylon-cotton
coated with water-repellent chemicals, and an inner layer of polyurethane foam
bonded to a nylon tricot fabric impregnated with charcoal. The water
repellent chemicals consist of an aluminum salt of a saturated carboxylic acid
(such as format, acetate, palmitate, or stearate) mixed with refined mineral
vegetable waxes (2). The clothing provides protection for the wearer against
vapor, aerosols, and small droplets of liquid agents, and will afford at least
6 hours of protection from agent penetration (1).
5
Ficurg 1. CBR Protective Field Mask, ABC-M17 and Hood, ABC-M6A2
6P
- INLET VALVE OPENING
NECK CORD
LEATHEROR
METAL
STRIP BINDER
THONG FASTENER
Figure 2. M6A2 Protective Field Hood
7
1 .-i °J
4r-,
=
L.3
C.,
iL
8•
4.4 The Gloves.
The glove sAt (shown in figure 4) provides hand protection against
vapor, aerosols, and small droplets of agents. The set consists of an outer
glove to provide agent protection and an inner glove to assist in absorption
of perspiration. The outer 5-finger glove is made of an impermeable and
unsupported butyl rubber, and the inner glove is made of cotton. Upon
contamination, the glove set affords at least 6 hours of protection from agent
penetration (1).
4.5 The Overboots.
The footwear covers (overboots, shown in figure 5) are worn over the
standard boot and under the trouser legs to provide protection for the feet
against exposure to all known agents in any form. The overboots are made of
impermeable and unsupported butyl sheet rubber. Upon contamination, the
overboots also afford at least 6 hours protection from agent penetration (1).
5. AGENT BEHAVIOR ON PROTECTIVE GEAR AND ITS RELATION TO DECONTAMINATION
Agents disseminated in vapor, aerosol, liquid, or thickened form can
be transferred to the surface of protective gear by contact. Once protective
gear is contaminated, agents begin to penetrate into the inner layers of the
protective materials. The rate of penetration is dependent on the following
factors:
* Concentration and amount of agents initially transferred
0 Agent vapor pressure
0 Agent forms (i.e., vapor, liquid, or thickened)
0 Material properties
* Meteorologkcal parameters.
9
Figure 4. Chenmical Protective Glove Set
Figure 5. Footwear Cover, Chemical Protective (Overboots)
11
It is generally agreed that the higher the concentration or the larger the
droplet size of agents that initially appear on the surface of a contaminated
area, the faster the penetration rate. With respect to the agent form, it has
been observed that neat agent can be absorbed by or penetrate into permeable
materials very quickly--almost immediately upon contact with the material.
Thickened agent droplets remain beaded upon most surfaces and penetrate slowly
into the inner layer of the material. The penetration rate of an agent is
also vapor pressure dependent--the higher the vapor pressure of an agent, the
faster the penetration rate of that agent. For example, GD has much greater
vapor pressure than VX and consequently, penetrates clothing more rapidly. If
a large liquid agent droplet on the surface of clothing is exposed to a very
low wind (0.5 to 1.0 mile per hour) until all of the agent is either evapo-
rated or penetrated, the percent of penetration for VX and GD are 2% and 5 to
1C%, respectively (3). It has been indicated that a normal type of woven
fabric yarn can act as a multicapillary channel to suck in liquid agents from
the surface of the fabric and transfer them to the bottom base layer (4).
However, agent droplet volume must be sufficiently large enough to enable
penetration through the inner layers of fabric. It was estimated at Edgewood
Arsenal that the droplet size normally used in agent dissemination is not
large enough to penetrdte through conventional woven fabrics, but is soaked up
by the multicapillary spaces between the yarn (4). Resultant toxic effects
are actually a result of the emission, desorption, and penetration of vapor
from these absorbed liquid agents.
Agent desorption or evaporation occurs simultaneously when agents
begin to penetrate into material inner layers. The rate of agent desorption
and evaporation depends on meteorological parameters (i.e., wind, temperature,
humidity, etc.) and agent vapor pressures. The whole process of agent pene-
tration, absorption, and desorption continues in clothing until all agent
phases reach an equilibrium. This equilibrium is determined by the material
absorption isotherm and the ambient meteorological conditions. It is gene-
rally agreed that decontamination processes become Inefficient once agents
have penetrated into the material inner layer (i.e., only the residual agent
on the contaminated surface can be either physically removed or chemically
12
detoxified; penetrated agents will remain unaffected) (5). In addition, the
use of thickened agent further complicates the decontamination process.
6. LITERATURE REVIEW
Since World War I, numerous materials and systems have been developed
for decontaminating chemical agents from a variety of substrates. The princi-
pal agents of concern are listed below:
* Bis(2-chloroethyl) sulfide; HD (Distilled Mustard)--neat or
thickened
* Isopropyl methyl phosphonofluoridate; GB (Sarin)
* Pinacolyl methyl phosphonofluoridate; GD (Soman)--neat or
thickened
* O-ethyl $-2-diisopropylamino ethyl methyl phosphonothiolat VX.
Current decontamination materials and methods can be generally classi into
3 categories: physical, biological, chemical. The following subsections
which detail the literature intormation in each category were evaluated in
order to determine the feasibility of decontamination application for the MCCA
system.
6.1 Physical Methods.
Many physical approaches have been cited in the literature for decon-
taminating agents upon a variety of substrates. These approaches include the
use of moist heat (6), dry heat (6), reverse osmosis (7), microwave (6),
ultraviolet irradiation (8), ultrasonic vibration (6), molten salt incinera-
tion (8), laser (9), pyrolysis (8), infrared (6, 10), photodecomposition (11),
sorbents (12, 13, 14), and ccntainment materials (12). However, because of
safety-considerations, from the above list, only sorbents and containment
materials are potentially feasible for decontaminating wounded personnel,
therefore, only these substances will be reviewed in this subsection.
13
6.1.1 Sorbents.
The use of sorbents as decontaminating materials for skin and other
surfaces have been studied extensively since 1918. The results of these
studies, repeatedly reported by many countries, generally agree that activated
charcoal and Fuller's Earth (Surrey Finest) can be effective decontamination
materials. Carbonaceous materials have been shown to be the best sorbents for
gases because of their nonspecific nature, high sorption capacity, and fast
sorption rates. For tP's reason, ASC whetlerite (a steam-activated bituminous
coal impregnated with various metals) is currently used as filter material in
all types of masks and collective protection devices, while Pittsburg-
activated charcoal is impregnated into clothing. It was reported (12) that
charcoal powder (in the form of the commercial item. Nuchar), when gently
dusted and rubbed onto the clothing surface (at a ratio of 2 rmg/cm 2), is
effective in reducing agent concentration, while allowing time for litter
persons to remove their protective clothing without exposure.
Fuller's Earth is a clay-type material and can nonselective. decon-
taminate agents. Although Fuller's Earth miy permit some insignificant agent
desorption, the desorption problem can be nr ,iimized by using excess amounts of
Fuller's Earth to retain the absorbed agen,.. 'he removal e vic" cy of
Fuller's Earth for V and G from rabbit and human skin has been reported to be
as high as 85 to 95% in laboratory studies, although somewhat lower results
were obtained in field studies (13). Limited work has been conducted regard-
ing the effectiveness of Fuller's Earth for decontaminating clothing. When
used on porous or absorbent surfaces, the decon~aminatlon capability is gene-
rally less effective (13). Also, the sorption rate was noticeably much less
with the thickened agents. The effectiveness of Fuller's Earth as decontami-
nation material was subsequently confirmed (4, 13). After comparison studies
of 22 domestic Fuller's Earth and two non-Fuller's Earth sorbent powders, it
was reported that Fuller's Earth, regardless of its origin, is a very promis-
ing sorbent for removing agents. The report indicates that among non-Fuller's
Earth materials, "Hazorb" is too slow In sorption rate, and silica gel (in the
form of the commercial item, Comet) is very low in sorption capacity for
agents. It was noted (4) that none of the investigated synthetic polymeric
sorbents were as good in sorption capacity as Fuller's Earth. However, the
14
report indicates that alumina powder (100 to 140 mesh) has the highest sorp-
tion rate. Although silica gel (Comet) is low in sorption capacity, it is
anticipated that silica gel can be a good sorbent powder if it is purified and
activated. For this reason, Warsaw Pact nations have used powdered silica gel
in their IMP Kit (13). It was reported (4) that when silica gel is combined
with clay powder and formulated into a pressurized aerosol spray system, up to
801 of an agent can be removed from clothing without a rubbing ii procedure.
Phenolic-type chemicals are known to hold G effectively by hydroqen
bonding and are considered to be possible sorbent material(s) for agents. A
preliminary test was conducted on nitro- or fluro-phenol impregnated clothes
to evaluate their retention effectiveness for agents: results indicated that
these phenol derivatives effectively held G and V, but were inadequate
against H (4).
Other sorbent formulations, such as aqueous charcoal slurries (23 to
28%1 in water plus corrosion inhibitor and antifreeze compound, have been
,.- tioned (7) for decontaminating agents, although promising results were not
reported. A mixture of activated charcoal, thixotropic agent, dispersant, and
antifreeze formulation, which can be easily sprayed over a contaminated
surface, was suggested (15). However, no test had been conducted.
Sawdust, soil, silicone, coal dust, amine or sulfonic acid-containing
polymers, organic and inorganic ion-exchange materials, and metal oxides have
been mentioned for absorbing agents (15, 16) but have not been practical. It
is interesting to note that after testing of several household products, it was
concluded (17) that flour, followed by an after treatment with water (wet
tissue-paper), can effectively remove all agents from freshly contaminated
skin.
6.1.2 Containment Materials.
Potential candidate containment materials that can be used for decon-
tamination by means of blocking and covering agents were tested (12);
15
12 compounds were recommended as the most promising candidates for future
optimization testing. These compounds can be classified into four categories
as indicated below:
* Natural products of gum-like materials
0 Synthetic gum materials
0 Latex systems
0 Others (e.g., carbonwax, sorbitol, sugar syrup, etc.)
It was mentioned (18) that linseed oil paint and nitrocellulose
lacquer coating have been successfully used for sealing agents onto contami-
nated surfaces, but these chemicals have never been used for large scale
decontamination.
An ideal containment which was not mentioned in the literatures is a
fast-setting polymeric system. However, this type of system is presently not
commercially available and requires development.
It was also indicated (12) that among the three application methods
tested (swabbing, fogging, and spraying), only the spraying method produced
satisfactory results (i.e., ease of application, adequate coverage, film
continuity, and containment efficiency).
6.2 Biological Methods.
The use of a cell-free enzymatic system, microorganisms, algae, and
the state-of-the-art genetic engineering approach for decontaminating chemical
agents has been cited (4, 19). Although this approach to decontamination may
be very promising for general demilitarization of ac .s. it is not recom-
mended for decontaminating wounded personne ',ecause of relative difficulty in
implementation.
16
A cyclodextrin type of complex containing many organic and inorganic
materials might react with agents in a manner similar to complex enzymatic
reactions. However. experimental data were not promising (4).
6.3 Chemical Methods.
Three types of chemical mechanisms--water/solvent or detergent wash,
oxidation, and acid/base hydrolysis--have been used for decontaminating
agents. Each type of chemical reaction will be systematically reviewed in the
following subsections. H and V contain sulfur moieties that are readily sub-
ject to oxidation, while V and G contain phosphorous groups that can be hydro-
lyzed. Therefore, most decontaminants are designed either to oxidize H and V
or hydrolyze V and G.
6.3.1 Water/Solvent or Detergent Wash.
A simple water or sea water wash serves two purposes:
* The removal of agents by mechanical force
* Slow hydrolysis of the agents.
The low solubility and slow rate of dissolution of agents in water are the two
key factors that limit the agent hydrolysis rate. The addition of detergent
to the water can increase the solubility of the agents. However, detergent
solutions have been shown to be no more effective than water alone for
H decontamination (20,21).
The use of an organic solvent wash as a decontamination method offers
some advantage over water systems because agent solubility in organic solvents
is generally much greater than in water. However, the main disadvantages of
solvent washes are:
* Solvents do not destroy agents, but merely solubilize them
* Solvents may carry agents through the garment to the skin.
17
The most effective organic solvents being used for agent decontamination
are JP-4, diesel oil, gasoline, kerosene, alcohol, and acetylene
tetrachloride (20, 22).
After washing, water or organic solvents will contain the toxic agent
and have to be collected for disposal. Also, they must be handled carefully
to avoid spreading the contamination. These disadvantages are sufficient to
exclude their application for the current project.
6.3.2 Oxidation.
A variety of oxidative chemicals have been used for agent decontami-
nation. Each type of oxidative compound will be discussed in the following
paragraphs:
0 Hypochlorite salt (sodium or calcium)--These compounds are very
corrosive. Chemical reactions involving these compounds are
very violent and exothermic when the oxidant is in a solid
phase. The reaction becomes easily controlled when the oxidant
is in the form of an aqueous slurry. Bleach, VH (0.2% calcium
hypochloride in buffered water), and SLASH (0.5% calcium
hypochloride, 11 sodium citrate dihydrate, 0.21 citric acid
monohydrate, 0.05% detergent, and 98.251 water) all contain
calcium hypochlorite and have been used for decontaminating
agents from contaminated buildings, floors, the ground, and from
various large-scale surface areas (23). Among these detoxi-
cants, bleach is most extensively used for hazardous materials
decontamination although it is relatively unstable.
Four forms of bleach are commonly used in these applications:
-- A 5% aqueous sodium hypochlorite solution
Supertropical bleach (STB) contains chlorinated lime and
calcium hydroxide containing more than 30% chlorine
18
High test hypochlorite (HTH) contains a solid form of
CaCIOCI plus calcium hypochlorite containing approximately
42% chlorine
Dutch powder contains calcium hypochlorite and magnesium
oxide
Among these detoxicants, HTH, having the highest percentage
of available chlorine, is most often used for decontamina-
tion (7, 24). Although the chemical reaction rate for HD and
bleach is relatively slow (7), bleach decontamirnates V rapidly
with a half life of 1.5 minutes at pH 10. STB has been used by
the U.S. for large-scale agent decontamination, while chloride
of lime (calcium hydroxide), containing at least 35$ active
chlorine, has been used by Russia for terrain and building
decontamination (25). Sodium hypochlorite (5.252) has been
mentioned in the literature as skin decontaminant for V (26).
The effectiveness of Dutch powder for decontaminating all three
agents (H, G, and V) has long been recognized by NATO countries
and the U.S. (5, 13). It was reported (27) that Dutch powder
can effectively decontaminate agents on vehicle surfaces.
However, the subsequent cleaning process is hampered because the
end-product mixture tends to adhere to the vehicle. For skin
decontamination, the active ingredients of Dutch powder have
been replaced by a less exothermic compound, MgOCaClOCI (13).
Sodium dichloroisocyanurate (DCICNR or Fichlor CDB-63) and tri-
chlorotriazinetrione (TCTATO)--These two compounds have chemical
reactions similar to HTH. However, they are considered more
aqueous stable and soluble than other chloramine salts (such as
chloramine -B, T, etc.), and have been used for laboratory-scale
decontamination of all agents on painted surfaces (7). After
2 weeks storage at room temperature, it was reported (28) that
DCICNR or TCTATO impregnated clothing can be effectively
19
protected against HD attack. However, these chemicals
destructive capability toward G and V was not evaluated.
0 Chloramine-B and chloramine-T--These two compounds, when com-
pared to HTH, are very stable, water-soluble, and less corrosive
to skin although they are relatively expensive. Never-the-less,
they have been incorporated into the M258/258AI decontamination
kit to detoxify HD and V (7, 16). By mixing the chloramine-T
with a VX simulant, malathion(diethylmercaptosuccinate S-ester
with o,o-dimethyl phosphorodithioate), in a surface activated
displacement solution 11 (SADS I!), it was reported (29) that up
to 99.5% of the malathion was destroyed within I minute in the
temperature range of 5° through 45° C. This report shows that
chloramine-T outperformed all other tested chemicals in
SADS II--hypochlorite salt, persulfate salt, perborate salt,
formaldehyde, and sodium hydroxide. Further testing was con-
ducted by spraying the chloramine-T-SADS II solution on a
malathion-contaminated painted aluminum surface. It was found
that approximately 68% of the malathion was destroyed (29). In
Russia, DT-1 (monochloramine-B or sodium benzene sulfonchlora-
mine) in dichloroethane has been practically !sed for
H decontamination of skin, clothing, and equipment.
* Dichloramine-B and dichloroamine-T--These two compounds are
water insoluble and are unstable when exp ;ed to sunlight and
moisture. They are readily soluble in many organic solvents in
which H and V are soluble and thus have been used for decontami-
nating these agents (7). In Russi-, DT-2 (dichloramine-B or
dichloramide of benzene sulfonic acid) in dichloroethane has
been used for decontaminating H on metal surfaces; DT-27
(dichloramine-T or dichloramide of p-toluene sulfonic acid) in
dichloroethane has been used for decontaminating H on wooden and
metal surfaces; DT-6 (hexachloromelamine or hexachloramino-S-
triazine), DTS-CK (aqueous slurry of di-tribasic salt of calcium
hypochlorite with sodium silicate), ethanolamine, solution I
(8% solution of DT-6 in dichlorethane plus IOZ DT-2 or DT-2T in
20
dichloroethane), solution II (mixture of 2% sodium hydroxide,
5% monoethanolamine, and 201 NH4 OH), and other similar formula-
tions (such as EF 1-1, EF 1-2, and EF 1-3) have been employed by
Russia as decontaminants (25). Solution I has been reported to
be good for H- and V-gases; solution II is good for G; DTS-CK is
employed as a general-purpose decontaminant (21, 25). Other
compounds belonging to this group include the following:
-- N-chlorosaccharin
N-chlorosuccinimide
N-chlorophthalimide
N-chloroacetamide
- is-(2.4.6-trichlorophenyl) dichlorourea
N-(2.3.6-trichlorophenyl) N-chlorobenzamide
DANC: 7% solution of 1,1-methylene bis-[3-chloro-5.5-
dimethylhydantion (S-210 or RH 195) in tetrachloroethane]
N-chlorosaccharin in pH 8.6 aqueous solution was predicted to
have shortened the half life of V to 10-4 seconds, but low water
solubility among other factors has actually prevented applica-
tion of this compound (7).
XXCC3, which is a combination of CC2 [Bis-(2,4,6-trichloro-
phenyl) dichlorourea] with 10% zinc oxide stabilizer (a solvent-
binder type substance), has been incorporated into ABC-M13
decontamination kit and impregnated into clothing materials for
agent protection, especially versus H and V (28). XXCC3 was
further tested for use in a microencapsulation concept. Pre-
liminary results indicated that O.30g of ethyl cellulose
21
microcapsules which contained 75% of XXCC3 would deactivate 871.
of neat H (0.02g) in less than 1 hour (28).
DANC has been used extensively in the past for decontaminating
agents. However, the high toxicity of tetrachloroethane and its
corrosive effect on paint surfaces and rubber limit the use of
DANC. In addition, DANC is ineffective against G.
Chlorine and chlorine dioxide--The chemical reaction of these
two compounds is very rapid and strongly exothermic hence,
suited for large scale demilitarization of agents. Because of
the highly corrosive nature of chlorine and the explosive
property of chlorine dioxide, their use as decontaminating
agents is quite limited.
Potassium permanganate--This compound reportedly detoxified V at
a 20:1 molar ratio (7). However, the rate of destruction was
not determined. It was reported (18) that 2.5% potassium
permanganate solution did not effectively decontaminate H.
* Potassium peroxydisulfate--This compound combined with a silver
ion catalyst has been suggested for the decomposition of V, but
experimental work has never been conducted (7).
0 Chromic acid--Chromic acid in concentrated sulfuric acid
solution reacts readily to oxidize H completely (18), but this
solution is extremely corrosive.
* Ozonated air--It converts H into the sulfoxide, but its use is
not practicable because the amount and concentration of ozone
generated by commercial ozonators is inadequate (18).
Metallic peroxides, benzoyl, and hydrogen peroxides--These
compounds react slowly or not at all with H, and are too inert
for practical use (18).
22
N-bromo organic compound--In an attempt to search for a new
oxidant which is noncorrosive and nontoxic, 3-N-bromo-4,4-
dimethyl-2-oxazolidinone (NBO) was found to be very effective
for agent decontamination (30). In a 0.03M NBO solution
containing the surfactant cetyltrimethylammonium chloride (CTAB)
at pH 9.5, it was found to be effective against all agents.
Unfortunately, logistical burdens restrict the use of this
formulation (e.g., it requires 6 to 18 moles of NBO to destroy
one mole of VX. In addition, the low solubility of NBO in water
has actually li.mited detoxification capacity of agents).
* Catalytic free radical systems--Catalytic oxidation is probably
not feasible at room temperature within the present state-of-
the-art (4, 7). It was further indicated (4) that other
catalysts, such as silicones, silazanes, metal salts, and organo-
metallic compounds can not accelerate the reaction rate to meet
the stringent criteria delineated in this report's introduction.
* Ionic polymers containing sulfuric or phosphoric acid functional
groups--These polymers were reported not to be effective against
agents (28).
* Miscellaneous Oxidants--Perchloryl fluoride (C10 3 F) and dinitro-
gen tetroxide (N20 4 ) were developed and tested (31); results
indicated that none of these new oxidants can effectively decon-
taminate agents. Sodium chlorite and sodium chlorate were tested
for their decontamination ability toward H, but were found no
more effective than bleaching powder (18). Polyacrylamidoxime
and a unknown product formed by reaction of chloroacetylhydro-
xylamines with alkyldimethylamines showed very good reactivity
with DFP and paraoxon (agent simulants), but no detailed data
were given (32).
23
6.3.3 Hydrolysis.
Chemical hydrolysis reactions can be classified into two types: alka-
line and acid. Acid hydrolysis is less important for agent decontamination
because the hydrolysis rate is slow and acid catalysis is rarely observed. For
this reason, the detailed hydrolysis mechanism for agents in acid solution will
not be discussed. Alkaline hydrolysis is initiated by the nucleophilic attack
of the hydroxide ion on the phosphorus moiety. The hydrolysis rate is depend-
ent upon the chemical structure and reaction conditions such as pH, tempera-
ture, the kind of solvent used, and the presence of catalytic reagents. The
hydrolysis rate increases sharply at a pH higher than 8. Since hydrolysis is
primarily catalyzed by the hydroxide ion under alkaline conditions, the hydro-
lysis rate is proportional to the concentration of hydroxide ion. In general,
the hydrolysis rate increases tenfold with each additional pH unit.
Temperature also influences hydrolysis rates. It has been estimated
that the rate increases about 4 times for every 10" C temperature rise.
Because the type of solvent used also greatly affects the hydrolysis rate,
surveyed decontaminants will be discussed in three solution classes: aqueous,
partially aqueous and non-aqueous:
0 Aqueous solutions--The hydrolysis rates for G and V are propor-
tional to the concentration of hydroxide ions, while for H, the
hydrolysis rate in any solvent solution is essentially the same
as that in water alone. It was reported (7) that hydrolysis
rates for GS• and V are less than I second and 0.2 hour respec-
tively at pH 13 and at ambient temperature. However, the actual
rate will be slower because the solubility of the agents in
water is not great.
Many bases have been studied and used for agent decontamination.
Although sodium hydroxide and ammonium hydroxide have been men-
tioned for hydrolyzing H, their effectiveness is not known
because of contradictory results (7, 21). Also, these bases had
been reported as nonuseful for large-scale decontamination of H.
In contrast to H, aqueous sodium hydroxide has been used in a
24
standard method for the decontamination of bulk G from munitions
and occasionally for V (7). Sodium hydroxide (caustic soda or
soda lye) and potassium hydroxide (potash lye or potash solu-
tion) have been used for equipment and terrain agent decontamina-
tion in both U.S. and Russia. Sodium carbonate (washing soda),
which is less corrosive, has been used for destroying GB. The
half life of GB in aqueous solution was reported to be
8.5 seconds (7). Again, the low solubility of GB in solution
hampers its decontamination application.
A number of other strong basic solutions have been mentioned for
agent decontamination. These solutions include aqueous ammonia
(water containing up to 25% ammonia with or without additional
alkali), trisodium phosphate, and sodium silicate. Aqueous
ammonia (weak solution with no precise concentration) has been
used for skin, clothing, and personal equipment decontamination
by Russia (25). Gaseous ammonia has also been mentioned for
clothing decontamination.
In an attempt to develop a new water-based decontamination for-
mulation (noncorrosive, nontoxic, and logistically acceptable)
to be effective against all agents, several novel nucleophiles
have been synthesized and tested for their destructive capability
toward agents. The test results indicated that micellar aldo-
ximes (1-n-dodecyl-3-pyridinium aldoxime salts) at a pH around
9.5 are good reagents for destruction of G and V, but are inef-
fective against H (24, 30). All other novel nucleophiles, such
as cetyldimethyl (2-hydroxyethyl) ammonium bromide, cetyldimethyl(2-mercaptoethyl) ammonlum bromide, and N-methyloctanohydroxamic
acid were found to be ineffective in agent decontamination (30).
A number of metal ions especially those of copper (II),
uranium (VII), zirconium (IV), thorium (IV). and molybdenum
(VI), have been observed to increase the hydrolysis rate of
agents in water. Some metallic salt solutions, which are less
corrosive, have been experimentally tested for their feasibility
25
in decontamination of agents, (e.g., uranyl nitrate with
tetramethylethylenediamine. and uranlum-dioxy-bis-(5-sulfo-8-
hydroxyquin-oline)]. However, preliminary test results indicate
that these chemicals are too slow for agent detoxification (7).
It was suggested (33, 34, 35) that bidentate nitrogen donor
ligand to Cu (II) with water and/or hydroxy ligands occupying
the remaining positions in the square-planar first-coordination
sphere, are more effective as hydrolysis catalysts than the
corresponding hydrated metal ions. The most effective ratio of
amino nitrogen to Cu (11) was found to be 2:1. It was indi-
cated (33) that the half life of GD in 1:1 ratio of Cu (11):
tetramethylethylenedlamine (TMEDA) is 1.0 minute at pH 7.0.
Although several diamine - Cu (II) complexes including
di-u-dihydroxo-bis-(N, N,N',N'-tetraethyl-ethylenediamilne)
dicopper (II) dlperchlorate have been postulated for incor-
poration into polymeric resins for agent decontamination (33),
experiments were not carried out.
Partially aqueous solutions--Both water and some organic
solvents are ingredients of these decontamination systems. It
should be noted that this type of system has been only applied
to small-scale decontamination purposes such as skin, cloth, and
other small surfaces. Some examples of these systems follow:
Fifteen percent (15%) sodium sulfide in a mixture of
gylcerol, ethanol, and water has been used to destroy
VID (7). The total destruction of HD at ambient temperature
requires 20 hours (21).
Quaternary ammonium hydroxide, sodium hydroxide, or
phenoxide in a mixture solution of dimethyl sulfoxide and
water or alcohol has been reported to be an effective skin
decontaminant for HL) (7). However, its effectiveness
against G and V was not mentioned.
26
A mixture of 701 methyl cellosolve and 30% of a 50% aqueous
sodium hydroxide solution gave complete destruction of HD
in 2 hours (7). This mixture has a relatively large
capacity for HD decontamination and is more favorable than
other H decontaminants (7).
Two emulsion formulae, Turkey red oil (5%), 95% ethanol
(35%), and sodium hydroxide (2.5%) in water; magnesium
oleate (2.5%), lubricating oil (20%), and calcium carbonate
(3%) in water have been used for H decontamination (18).
The rate of emulsion for H was reported to be rapid, but
the rate of hydrolysis was slow. Currently, an all-purpose
emulsifying decontaminant has been developed by
unidentified foreign powers for vehicle and equipment
decontamination (21). This emulsion consists of 8% calcium
hypochlorite, 15% perchloroethylene, 11 emulsifier (unspeci-
fied mixture of alkylbenzene sulfonate and polyglycol
ether), and 76% water. Field tests indicated that this
formula was capable of H and G decontamination but was
ineffective for V.
Nonaqueous solutions--The main advantage of nonaqueous
decontaminant systems is that the agent is usually more soluble
in organic solvents, hence, promotes a more homogeneous contact
of agent and decontaminant molecules; intimate contact of the
two reactants increases the chemical reaction rate. In some
cases, however, the dielectric constants of the organic solvents
are lower than that of water, and may actually slow the
reaction. The following statements detail the nonaqueous
decontaminants identified in the literature:
DS-2 as an all-purpose and yet effective decontaminant has
been cited by numerous reports (7). It is a relatively
corrosive superbase which consists of 701 diethylenetri-
amine, 28% 2-methoxy ethanol, and 2% sodium hydroxide. The
half lives for HD, GB, and VX in DS-2 at room temperature
27
were found to be less thdn 3 seconds, 30 seconds, and
7 seconds, respectively (7). Although an attempt was made
to improve DS-2's decontamination effectiveness (i.e.,
faster, less corrosive, etc.) by modifying the formulation,
none of the substitute formulations were found to be
markedly superior to DS-2 (7, 36). It was reported (12)
that the decontamination ability of DS-2 sprayed on
clothing coupons is far better than either 10% peracetic
acid, 10% monochloroperoxyacetic acid, hypochlorite acid
(0.15M), uranyl nitrate (0.1M), or thorium nitrate (O.IM).
During an attempt to determine the effectiveness of DS-2 as
a mist for the decontamination of agents on the M17 and
XM29 mask components, it was found that DS-2 did not cause
a change in the agent (H, G, V) permeation rate for butyl
rubber up to 1000 minutes even though DS-2 contains a
solvent fraction. Also, results indicated that DS-2 did
not cause any operational problem associated with the
filter (5).
Air Force CD-I (also known as APD) is also an all purpose
decontaminant. It consists of 551 (V/V) of monoethanol-
amine, 45% (V/V) of 2-hydroxyl-l-propylamine, 25% (Wt/V) of
lithium hydroxide monohydrate. When VX is in APD (1% of YX
by weight), up to 99% of VX disappeared in 15 minutes. For
GB, up to 99% of agent was destroyed in 2 minutes. When
compared to DS-2 under the same laboratory conditions, CD-I
is less desirable for decontamination not only because CD-i
destroys HD slower than DS-2 but also because the end prod-
uct of the APD and HD mixture is still quite toxic (7, 37).
Sodium hydroxide in methanol or ethanol has been experi-
mentally studied for decontaminating V. The results are
not promising because of the slow hydrolysis rate (i.e.,
half life is approximately 11 hours) (7). Sodium hydroxide
in dimethyl sulfoxide (DMSO) as a superbase has been
suggested for decontaminating HD, but no tests have been
28
conducted (7). However, DMSO is an excellent solvent and
possibly could carry unreacted agent through the protective
garment to the skin.
Benzyltrimethylammonium hydroxide in methanol has been
studied by the Navy as a potential decontaminant. No
detailed data have been released (7).
Monoethanolamine (MEA), an organic solvent which in itself
is a relatively strong base, has been used for decontami-
nating HD. The half life of HD is 32 minutes at 25° C when
the ratio of agent to decontaminant is 2 to 1 (V/V) (7).
MEA combined with 4-(N,N-dimethylamine) pyridine has been
used for GB decontamination (7, 28); results indicated that
GB was almost completely destroyed on contact. Similar
types of strong-base bulk reagents which are available in
storable formulations are lithium hydroxide in MEA and
sodium hydroxide and diethylenetriamine in methyl
cellosolve (28). However, their effectiveness against V
was not reported.
Alpha nucleophiles, even though less basic than the above-
mentioned bases, will attack and react with agent more
rapidly than hydroxide ions. This is because alpha
nucleophiles present an unshared electron pair on the atom
next to the one bearing the negative charge. Hydroper-
oxide, oximes, and hydroxamic acid compounds are examples
of alpha nucleophilic reagents. A number of theoretically
promising alpha nucleophiles have been synthesized such as
oxintinovaleroni tri le, ethylenediaminetetraaceto-hydroxami c
acid, amylose oxime, and fluorobenzaldoxime. However,
these compounds decontamination capability is yet to be
determia ned.
Pyrocatechol and pyrogallol anions are bidentate nucleo-
philes and were found to hydrolyze organophosphate rapidly.
29
Here too, agent decontaminating capability is yet to be
experimentally determined (28). Oximes with a large
aliphatic moiety should enhance organophosphate hydrolysis
rates [e.g., the half life of VX in a pH 9.3 solution
containing dodecylpyridinium-3-aldoxime iodide (10-3 M) is
40 seconds] (7); no decontamination experiment has been
conducted.
Macrocyclic ether-alkali metal salts, organic complexes,
have been examined for their decontamination capability
toward agents at or near room temperature in non-aqueous
solvents (38). Among five of the macrocyclic ethers
investigated, cryptand (2,2,2) and 18-crown-6 were most
effective in facilitating agent destruction. In absolute
ethanol, with a 1:1 equivalent concentration ratio of crown
ether and agent, the crown salt with potassium hydroxide
complex destroyed 98, 99, and 1002 of HD, VX, and
cyclohexyl methylphosphonofluoridate (GF) (a GB analog),
respectively, in 5 minutes (38). Because alkali metal
hydroxides are too corrosive for use on skin, a salt of
this reagent, the potassium acetate-crown complex in
benzene has been tested for its decontamination capability
against agents. The results showed that 54% of GF, 82% of
VX, and 99% of HD can be destroyed within 2 minutes (38).
Although the preliminary study on agent decontamination by
macrocyclic ether-alkali metal salt complexes are quite
promising, relatively high toxicity of one of its members
has limited its' decontamination application (39). In
addition, because these macrocyclic compounds are not
generally available from commercial sources, the need for
synthesizing them in quantity will further hamper their
potential applications for this project. However, market
demand can readily reverse this situation.
Several other novel organic molecules reported in the
literature would require syntheses that are beyond the
scope of this project. Examples of these compounds are
30
bromodimethyloxazolidone, dimethylaminopyridine, poly-
ethylenimine, and imidazole (28). Unfortunately, their
detoxification capabilities toward agents are not known; no
evaluation data have been given in the literature.
7. CURRENT STANDARD DECONTAMINANTS USED IN THE U.S. ARMY
Before evaluating any new or relatively new potential agent decontami-
nants, the current status of standard decontaminants used by the U.S. Army
will be discussed. The U.S. Army presently uses both physical and chemical
approaches to decontaminate chemical warfare agents (24). These two standard
approaches are outlined below.
7.1 Physical Procedures.
Physical procedures do not detoxify chemical agents, but only remove
the agent from contaminated personnel, equipment, and/or terrain. One of the
most important large-scale physical removal methods is aeration, either
natural or forced, resulting in agent dispersal into the air. Natural weather-
ing, which includes forces other than air alone, (e.g., temperature, ultra-
violet light) is probably the most important decontamination procedure
available where time limitations are not a factor. Natural weathering, in
most cases, will not be applicable to decontaminating casualti. Ince the
time lapse prior to treatment must of necessity be short if exacerbation of
injuries is to he avoided.
Active physical removal approach includes the use of flat stick pads
containing Fuller's Earth (such as in the ABC-M13 Kit), heat in the form of
fire or steam, and high pressure water rinses. Another method is simple
washing with hot soapy water. Again, these approaches will not suffice for
processing casualties.
7.2 Chemical Procedures.
There are two general categories of chemical decontaminants presently
in use to detoxify chemical agents, standard and field expedient decontami-
nants. Standard decontaminants are those developed specifically for use by
31
military personnel, and field expedient decontaminants are those chemicals
that are readily available for use in a military environment.
The standard decontaminants are DS-2, supertropical bleach (STB), and
the components of the ABC-M13 and M258/M258AI decontamination kits. Table 2
lists the U.S. Army standard chemical decontaminants and the corresponding
agents they are effective against.
TABLE 2. U.S. ARMY STANDARD CHEMICAL DECONTAMINANTS
Decontaminant Agents Detoxified
STB Blister and Nerve AgentsDS-2 All AgentsABC - M13 Kit Blister and V- Series Nerve AgentsM-258 Kit/M258A1 Kit All Agents
STB may be mixed with water to form a wet slurry or it may be mixed
with dry earth, sand, or ashes to form a dry mix. The dry mix of STB has been
used by the Army in shuffle boxes to decontaminate boots (16).
DS-2 is a clear solution that is applied with the M11 apparatus to
contaminated areas.
The ABC-M13 individual decontaminating and reimpregnating kit is
designed to be used by individuals to decontaminate droplets of all chemical
agents on skin or clothing. This kit consists of a pad containing Fuller's
Earth powder for use in absorbing liquid agents plus two cloth bags of
chloramide powder (XXCC3) for detoxification purposes.
The M258 skin decontaminating kit consists of two capsules containing
decontamination solutions, two flat wooden scraping sticks, and four gauze
pads, in a plastic container. One of the gauze pads is used to soak up as
much liquid agent from the contaminated skin as possible. If the contaminant
is a thick liquid, it is first scraped off with the scraping sticks. A second
gauze pad wetted with solution I is then rubbed over the contaminated area.
32
Subsequently, the third pad is used to apply decontamination solution 2.
Solution I consists of sodium hydroxide, ethanol, and phenol, and is used to
detoxify G; solution 2 contains chloramine-B and zinc chloride in a water-
ethanol solution, and is used to decontaminate H and V. A modification of the
M258 Ki1t, the M258A1 Kit, has presoaked the decontaminating towelette sets
which are then used in a similar manner as the gauze pads.
A large number of field expedient decontaminants have been identified
by the Army for the detoxification of chemical agents. Among these are
ammonia (NH3 ), caustic soda (NaOH), sodium carbonate (Na2 CO3 ), lime (CaO),
laundry bleach (5% NaOCl), and trisodium phosphate (Na 3 PU4 ). Oxidation by
fire and steam hydrolysis are other field expedient techniques. These
decontaminants and techniques, however, are generally not :rfective against
all agents and cannct be used for obvious reasons on casualties.
.8. INDUSTRY SURVEY FOR AGENT DECONTAMINATION
Numerous telephone inquires and personal interviews with private
industries were conducted to search for new decontamination agents and
techniques. However, only a modest amount of information, which may be useful
for agent decontamination, was obtained during this survey. The results of
this investigation are summarized below. Organizations contacted during this
survey are listed in Appendix B.
8.1 Rohm and Hass Company (Spring House, Pennsylvania).
Three new types of high surface area polymeric resins have been
developed for application in agent decontamination. These three types of
resins are carbonaceous adsorbents, polymeric adsorbents, and reactive resins.
Each type of adsorbent is briefly described below, although specific
compositions, being proprietary, have not been revealed.
0 Carbonaceous adsorbent--These adsorbents have been found to have
higher gas phase dynamic capacities for simulants and agents
(HD, GD and cyanoaen chloride) than granular activated carbon.
The dynamic capacity of these adsorbents is not reduced when the
33
relative humidity is increased, even to 100%. Carbonaceous
adsorbent activity can be regenerated under mild conditions,
such as being purged with low pressure steam, hot air, or Pn
organic solvent. Under normal operating conditions, these
resins reportedly retain the agents more tenaciously than
granular activated carbon. The individual resin beads are very
strong and are resistant to attrition. Specific data have not
been released.
* Polymeric adsorbents--These adsorbents have been tested by Rohm
and Hass and found to have high capacities for simulants, such
as diisopropyl fluorophosphate and dimethyl methyl phosphonate;
capacities are well over twice that of granular activated
carbon. Tests of these materials with agents have not been done
to date. These polymeric adsorbents function well at high
humidity and can be regenerated under mild conditions according
to the company.
* Reactive resins--These resins are highly functionalized forms of
the polymeric adsorbents. They combine the high capacity of the
polymeric adsorbents with a wide range of active chemical
groups. These chemical groups include all of the groups
normally used in ion exchange resins and many groups which are
prepared specifically for chemical defense applications. Both
catalytic and stoichiometric reactions involving attached
functional groups have been demonstrated. Rates of reaction of
functional groups attached to polymeric resins can exceed the
rates of reaction of those groups attached to small molecules.
Many of the reactive resins investigated can be easily
regenerated. Reactive groups on polymers are far less corrosive
than the same free fu':ctional groups toward such substrates as
metal, paint, and skin. Again, data are not publicly available.
Comment: Reactive resins, which act as adsorbents, detoxicants,
and coatings could be very promising decontaminants for the
MCCA-M project if company claims are correct.
34
8.2 H. B. Fuller Company (St. Paul, Minnesota).
Three types of chemical materials, which could act as fast-setting
polymers to seal agents onto clothing, were recommended. Each type of
chemical is briefly described below:
* Low molecular weight wax--This material can be applied to
contaminated surfaces by spraying. Application temperature will
be around 1250 F, and spray pressure will be 30 psi (pounds per
square inch). Wax setting time is estimated to be less than 2
minutes.
0 Water based adhesive polyvinylacetate--This polymer can be
sprayed onto contaminated surfaces, but the setting time is
estimated to be longer than 10 minutes hence, of doubtful use in
handling casualties.
* Urethane powders (Product numbers VR2151 and VR2194)--These are
required to be pre-mixed before application. The setting time
is estimated to range from 30 seconds to 8 minutes, depending on
actual chemical formulation.
Comment: Low molecular weight waxes, which are nontoxic and
inexpensive, could be a feasible approach to sealing off agent-
contaminated clothing.
8.3 Chemical Coating dnd Engineering Corporation (Media, Pennsylvania).
Hypalon--This is a trade name for an elastomeric material that can be
sprayed after mixing with an organic solvent, such as acetone or hexane; it
can set within 2 minutes.
Comment: Organic solvents may enhance the penetration of agents into
the inner clrthing materials. This product cannot be recommended for use as a
decontaminant at this time.
35
8.4 3M Company (St.Paul, Minnsota).
Spray adhesive (3M-77)--This adhesive has been formulated into
aerosol form.
Comment: A very small amount of 3M-77 spray adhesive can be sprayed
onto contaminated surfaces followed by dusting with a containment powder.
Results of this application may be similar to those obtained from use of
fast-setting polymers which act as sealants for agents.
8.5 Lab Safety Supply Company (Janesville, Wisconsin).
Sticky mat--These are paper-type sheets with sticky surfaces that can
be used to wrap around contaminated casualties still in MOPP-level 4 gear to
serve as a sealant against agents.
Comment: Preliminary tests indicate that the existing sticky mat
requires modification and improvement In order to satisfy this project's
requirements. The product currently available did not adhere to standard
protective garb. However, the concept of using sticky mat for wrapping around
contaminated casualties is a novel one.
9. EVALUATION AND ANALYSIS
Theoretically any decontaminant which does not meet the criteria
delineated in this document's introouction shall be excluded from further
analysis. However, CSC-EL personnel believe that a systematic screening for-
potential decontamlnants is feasible. Based on the information outlined in
the Section 6. and 8. (i.e., Literature Review and Industry Survey for Agent
Decontamination), the top three or four potentially most efficient decon-
taminants in each feasibility category were selected and listed in table 3 for
comparison and trade-off analyses. The data for each decontaminant in table 3
were obtained either from the literature or from telephone inquires. Data
sources are listed in table 3 for referepce purposes.
36
TABLE 3. THE MOST EFFECTIVE DECONTAMINANTS IN EACH FEASIBILITY CATEGORY
ltafve O4AU of I Choie 1. kefo,.mc,Qhcv-uI1.4't C*e'vepIWss Staflltllo Saefty bbolecifcy lstfoweletm !tI.19. lm- os weAvo'kI
AI1108tt charcoal Nig 1190 osloc All 45 -401b 2 " 02 12. 11 list o- flielf' 4-eCl1
W.,*, I co't.. *fop diotosit All -M *Qc I 1 7, 14 NATO I "clsonum8.
Silic 911 pit lipaomi AllS atI N/A I/ Ai 14 se IR 041,98. PcLl is. kit
Wh'ist G5 Nigh diastlict All ft 011puesa I/A ZI stee.1 abso*#b.t
s~ucp so Pith b~tGAIC All go Pla.101 N/A 21 wooS 66'lpetbA
Pots64tt-g poly", 141A 41A r/A All so Plolates I I/A act cetion'clall, nL I
fATL/O1.AIIC 100(61.
ofte've~t 5410' ft Plot, Too All 45 time "to 12 Veol~ci 45OqcfUSIOIucn
.19.4 Iso "lop. 7blkjbI. All so Iles Aul 22 vehicle wCwtORUGIite
8110901 1111 N11,0 rIggodll All an 114V bull 22 Used9 *fU' 06 a 10'#I't fc,MiA' &B1tAUlima0
01192A,111 Ch(ICAts
PiYRIclrita "ilt k19p Low Toisc wow 11, v To$ di11.1., -6:1 7, 11 IL4 Aftp i%19I4'4
ClhloflivgIw S~ T0 Itlw Abolun 45E1 & usc PSC , v 1*1 011441114 -4o1 21. 29 C.,..met of 5259or ZIJI kit
liccl 4-thitrow..As 995.;) I1141D Milion ta,, Wauit N I To$ ollauta -10:1 7 C41WOeqt of AIC-UIJ kit,Prouctiso cvetol~o
C. .];*fl(CA foball Motion 1.4#1 toxlic All lot Ploutes 3: 23 99allilN tell data
05-2 Motu@ f4441I Yogic All Us1 491 1-I . US Ap" stIA44l4
cryoUld-sIOCIlU I.Y4910-o Noaion Nigh0 Toxic All w e$ stllites .2:A ?1 DPw411io wtdatlee
CrypUA4-I04lgs acnut. Lw. Kl159 Left 10611 All too Missiles P.4:1l~ &@a0115 t~l 041
lteactlit risll too "lop min. Usic All To$ alel as toI /A WOO5 aed Kill ft. PPeOUCt. (00 lItII 4110
Let 114.~18P 611151t -41 so 5195 5101"Wa All ft 11lM.us N2 . S. r.I I. ft too% mass
31-77-8p'a 7 s40egl,f so pith min, toxic All me 1101mata im. of Is ai 041
stickyata 01i p5 loop golail All w 11,101 SIP too saftyIt Priduct PI1.171 ftlfllCil'o
37
9.1 Sorbents.
Fuller's Earth is a very promising non-selective decontaminant which
physically absorbs the agent and has long been used by NATO for decontamina-
tion purposes. Activated charcoal and silica gel dust are second choices.
However, the disadvantage of sorbents is that they will not destroy the agents
which will eventually off-gas to again contaminate the environment. This may
consititute an acceptable risk if the sorbent Is removed in a timely manner
from the environment of concern. However, the physical nature of this
material may not only preclude ready removal, but may result in its distri-
bution into other areas of the 0helter. Never-the-less, it may be desirable
to have sorbents available for standby measures.
9.2 Containment Materials.
Containment materials (such as starch or ground corncobs) with
adhesive chemicals or fast-setting polymers that bond to both agents and
clothing, provide blocking and sealing effects. Although this approach does
not actually detoxify agents, it will generally fulfill the stated require-
ments of this task, because it will protect both wounded personnel and medical
staff from agent exposure in any form. It should again be emphasized at this
point that our concept of the function of the MCCA-M is to safely remove
casualties from contaminated gear without endangering attendant personnel
rather than the former concept of achieving complete decontamination.
Although subtle, the difference in concepts is important.
A fast-setting polymer (such as to a latex system) providing
excellent sprayability, film formation, and flexibility, is strongly favored
for this project. However, a fast-setting latex system is cucrintly not
available in the commerical market and is yet to be developed. An alternative
Involving sequential application of a 3M spray adhesive and then starch or
corncob powder may also meet the decontamination criteria. Reactive resins
(Rohm and Hass) and low molecular weight waxes (H. B. Fuller) are also to be
actively considered based on current available data and theuretical
projections.
38
9.3 Water/Organic Solvent.
Detergent-water, alcohol, and JP-4 are the most commonly mentioned
solvent systems for agent decontamination. However, these solvents cannot be
considered for decontamination of casualties due to obviously unsafe and
inefficient actions.
9.4 Oxidative Chemicals.
Among the oxidative decontaminants, ASH, SPLASH, HTH, STB,
chlorinated lime, and Solution I are apparently effective detoxicants.
However, because they present a toxic vapor hazard, are corrosive, difficult
to handle, and deteriorate with time even if in the dry state with added
stabilizer, they are excluded from consideration in the current project as
potential decontaminants.
Although Dutch powder is also a bleach-type decontaminant and
presents similar chemical properties to other chemicais (such as HTH and STB),
the modified Dutch powder, which has been used by NATO for skin decontamina-
tion, will be considered for later comparison analysis.
Hydrogen peroxide is a very good oxidative chemical, but it is too
unstable and explosive.
DCICNR, TCTATO, chloramine-B, and chloramine-T are also effective
oxidative compounds, but are not recommended as decontaminants for thisproject because they are water soluble; wetted clothing can result in agent
penetration of the protective gear. Dichloramine-B and dichloramine-T are
soluble in many organic solvents in which agents are soluble, but they are not
stable when exposed to sunlight and moisture. In addition, they do not
detoxify G effectively hence, do not meet current requirements. DT-1, DT-2,
and DT-6 in dichloroethane are noncorrosive and have been used by Russia to
decontaminate agents from skin, clothing, wood, and metal surfaces. However,
they are only recommended for H decontamination and do not meet the non-
selective criterium. DTS-CK is a general-purpose decontaminant, but it is too
corrosive and unstable for storage.
39
9.5 Hydrolytic Chemicals.
Among the hydrolytic group, DS-2, Cryptand (2,2,2) and its potassium
hydroxide complex, and the Cu(II)-TMEDA complex represent potentially the most
effective agent decontaminants in each type of classification. However, they
are relatively corrosive. Cryptand and potassium acetate in hexane solutions,
being less corrosive, can be an alternative decontaminant system if the more
corrosive decontaminant such as DS-2 are rejected by USAF.
Theoretically, a corrosive decontaminant (pH above 9) should be
eliminated from consideration. However, since only a measured amount (a
theoretical maximum of 150 gm/person) of these detoxicants will be applied
over the clothing surface and the decontamination process time is very
limited, the corrosive nature of these chemicals may become negligible. For
this reason DS-2, cryptand-potassium hydroxide, cryptand-potassium acetate,
.and CU(II)-TMEDA complex are being considered for the decontamination
feasibility tests in the later phase of this project.
After a detoxification reaction, the surface of the protective
clothing is likely to be coated by a layer of nondefined less toxic, oily,
organic end-product residues. This end-product may be difficult or
impractical to remove by chemical solvents or by brushing with abrasive
action. Although a complicated surface active solution may be developed for
washing out this residue, it may cause a clothing-wetting problem. Therefore,
a fast-setting polymeric/containment material coating or sorbent powder is
proposed and recommended for coplication over the chemical residues after the
detoxification reaction step in the procedure. The coating will provide a
more complete and thorough decontamination effect because it will not only
cover the organic residues of any kind but also will prevent agent desorption.
Based on the preliminary analyses mentioned above, table 4 lists CSC-EL
personnel's recommended potential decontaminants and their commercial
availaility.
40
TABLE 4. POTENTIAL DECONTAMINANTS AND THEIR COMMERCIAL AVAILABILITY
Decontami nation CommercialSystem No. Chemical Compositions Availability
1. Fuller's Earth Yes
Dutch powder Yes
2. Fast-setting polymer No
or
Starch or corncob with spray adhesive Yes
or
Low molecular weight wax Yes
or
Sticky mat No
3. DS-2--70% diethylenetriamine Yes-- 28% glycol monomethyl ether Yes-- 2% sodium hydroxide Yes
Sorbent or containment material Yes
or
Cu (ll)-tetramethylethylenediamine No
Sorbent or containment material Yes
or
Cryptand Yes
Potassium hydroxide Yes
Hexane Yes
Sorbent or containment material Yes
or
Reactive polymeric resin Yes
Sorbent or containment material Yes
4. Cryptand Yes
Potassium acetate Yes
Hexane Yes
Hot air Yes
41
Based on the results of the commercial availability analysis as listed in
table 4, four potentially feasible decontamination systems are recommended for
further examination. These systems follow:
* Mix Fuller's Earth powder with Dutch powder at a 1:1 ratio.
Apply this mixture evenly over the entire protective gear.
Shortly after completion of the chemical reaction, the end-
products will be removed by vacuum.
a Apply a fast-setting polymer, low molecular weight wax, or
containment material over the entire protective gear. The
containment material (such as starch or corncob) can be applied
after spray coating the protective gear with adhesive chemials.
An improved sticky mat may be used directly to wrap casualties
still in MOPP-level 4 protective gear.
* Apply a detoxicant chemical (e.g., DS-2; copper ligand;
macrocyclic ether-alkali metal-salt complex; reactive polymeric
resin) over the entire protective gear for agent decontami-
nation. After detoxification, sorbent or containment material
will be gently sprayed over the surface of the entire protective
gear to produce a protective "cocoon."
* Apply only cryptand and potassium acetate in hexane solution.
After detoxification, a flow of hot air will blow dry the
protective gear.
From the preliminary analysis, as mentioned earlier in this report, it isbelieved that only a few chemical formulations can currently qualify as all-
purpose decontaminants (preferably true detoxicants) which is one of the key
criteria delineated in this report's introduction. These formulae are DS-2,
CD-i, DTS-CK, and aqueous bleach. Among them, DS-2 has been generally
accepted as the most effective decontaminant for all known agents. Therefore,
it is suggested that test data from any decontaminant system be compared to
the data that results from DS-2 decontamination under the same test condi-
tions. After the final test data analysis, if DS-2 is still proven to be
42
superior to the other substances tested for decontamination capability and
efficiency, but is rejected by the USAF for safety reasons, the second and
third ranked decontamination systems may be recommended for incorporation into
the MCCA-M system.
A brief, highly tentative outline for the proposed decontaminationmethods follows. These methods are for stretcher-type casualties only:
0 Gently remove the wounded personnel from the standard stretcher
to a sheet of activated charcoal impregnated paper which is laid
on top of a specially designed platform.
* Seal the wounded area with a medical patch such as an Abd pad
which contains a broad spectrum antibiotic plus an absorbent for
chemical agents. The patch is covered with a sterile sheeting
(e.g., Op-Site).
* Replace the respiratory filter with a specially designed valve
(figure 6).
Air x . - - Filter
Figure 6. A Specially Designed Valve For
Replacement of the Mask Filter
43
* Wipe the mask eyelens outserts and voicemitter with a cloth
soaked with chloramine-B in alcohol (removal of eyelens outserts
is an option depending on which decontamination system will be
used).
* Cover the cleaned eyelens outserts and voicemitter with sheets
of sorbent papers.
* Slide the platform with the casualty into the decontamination
room.
a Mechanically apply one of the previously recommended
decontaminant systems.
* Slide the platform with the casualty out of the decontamination
room.
0 Use one or two corpsmen to cut the processed protective clothing
from the casualty in accordance with figure 7. Fatigues and
undergarments will also be cut away and placed in a separate bag
with a patient ID number to recover valuables, etc., when time
permits.
* Put the cut protective clothing, along with overboots, gloves,
and hood into a charcoal-lined plastic bag. Seal the bag which
is then ejected from MCCA.
* Remover the mask and replace with a disposable absorbent-
impregnanted nose and mouth piece. Place the mask in a plastic
bag for ejection to the outside.
* Immediately transfer the casualty to an absorbent material-type
stretcher. Specifications for the stretcher will be developed
later.
9 Cover the naked person with a sheet of adsorptive garment.
44
a Pass the casualty through an airlock into the medical TFA.
Note: It is again emphasized that the decontamination procedure outlined
above is tentative and will be modified as our data base develops.
I
I
III I
I I
Figure 7. Protective Clothing Cutting Lines.
45
10. DECONTAMINANT APPLICATION
As indicated in this report's introduction, the decontamination
process must be rapid (i.e., completed within 4.0 minutes) and essentially
automatic. For safety reasons, the decontaminant formulation must not
excessively wet the protective gear and should preferably be toxicologically
safe. It is understood that adopted chemicals and processing procedures will
not degrade the MCCA integrity. Seven detoxicant/decontaminant application
methods have been identified as indicated in the following list:
0 Spraying
* Powdering
* Fogging or misting
* Washing
0 Foaming
0 Containing
* Physically removing (i.e., whipping, swabbing, and rubbing etc.)
The methodology and equipment used for each of the above decontaminating modes
will be discussed in more detail following the decontaminant prioritization
decision (October 1984).
11. SIMULANTS
Simulants must adequately mimic chemical and physical properies of
the agents that are applicable to the test being done. For instance,
viscosity, vapor pressure, molecular weight, density, melting point, surface
tension, and chemical functional groups are all important parameters for
simulant selection. Although the properties of a good simulant should be
parallel to the properties of the mimicked agent, in the current project,
46
chemical functional groups and vapor pressure factors will be given priority.
Chemical functional groups will be used to evaluate the detoxification
capability of a decontaminant and vapor pressure factors will be used for
comparing the decontaminant sealing effect. The simulants considered in this
project correspond to the neat form of HD, GD, and VX, respectively.
Thickened agents present a special set of problems and will not be addressed
in the initial phase of this program.
Table 5 lists the simulants used in previous studies, which are cited
in the literature. At the preliminary stage of this study, diisopropyl
phosphonofluoridate (DFP) or malathion which has a labile phosphorus-leaving
group bound similar to that occurring in GD and VX, and 2-chloroethylmethyl
sulfide (CMS) which matches the hydrolytic characteristics of HD, will be
se3lected as simulants for GD, VX, and HD where true detoxification studies are
concerned. However, for testing of containment materials or fast-setting
polymers, dimethylmethyl phosphonate (DMMP) shall be chosen for its close
similarity in volatility to HD and GD.
TABLE 5. AGENTS AND THEIR CORRESPONDING SIMULANTS
Agent Corresponding Simulant
H CMS (2-chloroethylmethyl sulfide)
H TD (2,2 thiodiethanol)
GA OSP (0-ethyl-S-ethyl methyl phosphate)
GB DIMP (Diisopropylmethyl phosphonate)
GD DMMP (Dimethylmethyl phosphonate)
V,G DFP (diidopropyl phosphonofluoridate)
V Malathion (diethyl mercaptosuccinate S-esterwith o,o-dirnethyl phosphorodithioate)
V TBEP (tris butoxyethy! phosphate)
H,G,V DEM (diethyl malonate, thickened or neat)
7•"
12. CONCLUSION AND RECOMMENDATIONS
Based on the results of an extensive literature search, review, and
evaluation, in general, there is no single known decontaminant method that can
meet all required decontamination criteria. However, after a careful trade-
off analysis, market survey, and deliberation, CSC-EL personnel recommend four
potentially feasible decontamination systems for further testing, examination,
and comparison. These systems include a combination of two known decontami-
nant methods; several new industrial products; a family of copper ligands.
Following testing, the system showing most promise will be incorporated into
the MCCA system for casualty decontamination. The four recommended decon-
taminant systems are as follows:
* Mix Fuller's Earth powder with Dutch powder at a 1:1 ratio.
Apply this mixture evenly over the entire protective gear.
Shortly after completion of the chemical reaction, the end
products will be removed by vacuum.
* Apply a fast-setting polymer, low molecular weight wax, or
containment material over the entire protective gear. The
containment material (such as starch or corncob) can be applied
after spray coating the protective gear with adhesive chemicals.
An improved sticky mat may be used directly to wrap casualties
still in MOPP-level 4 protective gear.
* Apply a detoxicant chemical (e.g., DS-2; copper ligand;
macrocyclic ether-alkali metal-salt complex; reactive polymeric
resin) over the entire protective gear for agent decontami-
nation. After the detoxification reaction, sorbent or
containment material will be gently sprayed over the surface of
the entire protective gear to produce a protective "cocoon."
* Apply only cryptand and potassium acetate in hexane solution.
After detoxification, a flow of hot air will blow dry the
protective gear.
REFERENCES
1. Ctfemical Defense Design Handbook for Tactical Shelters--Volume I.Chemical and Biological Protection Handbook for Field Personnel. 1982
2. Military Specification: Cloth, Twill: Cotton and Nylon. 1974.
3. Objective and Systems for Decontaminating in the Field. 1971.
4. Research and Feasibility Studies cn Clothing and Decontamination.197G.
5. Personnel Decontamination Station. 1979.
6. Investigation of Techniqus for Decontaminating Personnel ProtectionItems. 1982.
7. Decontamination Methods for HD, GB, and VX--A Literature Survey.1981.
8. Chemical and Biological Warfare: Part II. Protection,Decontamination, and Disposal (1978-1982). 1982.
9. Chemical and Biological Warefare: Part I Protection,Decontamination, and Disposal (1964-1978). 1981.
10. Chemical Decontamination of Military Equipment Using Infrared Rays.1978.
11. Approaches to Decontamination or Disposal of Pesticides:Photodecomposi tion. 1978.
12. Methods and Material for Personnel and Equipment Decontamination;Final Report for Task No. 24 on Collective Protection Against CBAgents; Book I--Unclassified Data. 1970.
13. Sorbent Powder for Chemical Warfare Decontamination. 1982.
14. Survey of New Sorbents for Application to Protection Devices. 1976.
15. Compounding Techniques for Absorbent Decontaminants. 1972.
16. Chemical, Biological, and Radiological Decontamination. 1967.
17. Proceedings of the International Symposium on Protection AgainstChemical Warfare Agents Held at Stockholm, Sweden on June 6-9, 1983.1983.
18. History of Research and Development of the Chemical Warfare Servicethrough 1945: Decontamination of Chemical Agents, Part 1. 1970.
19. Detoxification of Pesticides Using Soluble or Immobilized Enzymes.1978.
49
20. Enineering and Development Support of General Decon Technology forthe U.S. Army's Installation Restoration Program. Task 5. FacilityDecontamination. 1982.
21. Survey of Decontamination Methods Related to Field Decontamination ofVehicles and Material (Abridged). 1978.
22. Decontamination Field Expedients--Summary of Results. 1980.
23. Military Chemistry and Chemical Agents. 1956.
24. Toxic Substance Control: Decontamination Symposium. 1980.
25. Chemical Warfare Capabilities--Warsaw Pact Countries. 1979.
26. Environmental Temperature and the Percutaneous Absorption of ACholinesterase Inhibitor, VX. 1977.
27. Exploratory Development of a System for the Decontamination of CombatVehicle Interiors. 1980.
28. Study of Reactive Materials for Development of New ProtectiveClothing Concepts, A. 1978.
29. Lontinued Investigation of Surface-Active Displacement Solutions/SADSII Detoxification and Application Data. 1982.
30. Evaluation of Decontamination Formulations. 1981.
31. New Oxidants and Mechanisms of Oxidation. 1967.
32. Decontamination of Surfaces Contaminated with Chemical Agents. 1978.
33. Phase I: A Feasibility Study on the Possible Development of ResinPolymer for the Filtering and Sensing of Chemical Agents. 1979.
34. Study of Agent-Reactive Fabrics for Use in Protective Cothing, A.1979.
35. Organophosphorus Pesticides: Organic and Biological Chemistry. 1974.
36. Development of Package Decontaminating System (Final Rept. 29 Jun71-29 Jun 72). 1972.
37. Studies on the Destruction of Toxic Agents VX and HD by theAll-Purpose Decontaminants DS-2 and CD-I. 1975.
38. Examination of Macrocyclic Ether-Alkali Metal Salt Complexes asDecontaminants for Chemical Warfare Agents in Non-Aqueous Solvents.An. 1979.
39. Brief Review of the Chemistry of Crown Ethers, A. 1976.
50
APPENDIX A
REFERENCE SYNOPSES
1. Chemical Defense Design Handbook for Tactical Shelters--Vol. 1.
Chemical and Biological Protection Handbook for Field Personnel.
National Aeronautics and Space Administration--National Space
Technology Laboratories--Engineering Laboratory
AD #: N/A
November 1982
This publication provides guidelines for ensuring safe operations of tactical
shelters in a CB environment.
Volume I includes procedures which can be used by personnel to operate
tactical shelters more safely in a CB environment. In addition to suggested
procedures, this handbook includes guidelines for modifying shelter operations
in order to minimize exposure to CB agents and spread of agent contamination.
Appendices provide listings and descriptions of chemical defense (CD)
equipment used by the USAF, Army, and Navy which is currently in the
inventory. In addition, industrial hygiene equipment has been surveyed and
serveral items have been selected for their potential usefulness in shelter
operations in a CB environment. Recommendations for suggested use of these
items are presented as well as their descriptions.
This handbook is primarily intended to be a ready reference for field use; the
detailed descriptions of CB protection equipment, CB agents, and CB defense
operations have been modified to provide only the most pertinent data in each
of these areas. References have been provided, however, for appropriate
technical reports, field manuals, and technical manuals, which contain
additional detailed descriptions of these areas.
51
2. Mi I i tary Speci f icati on: C I oth, Twi 11 Cotton and Nylon
Author: N/A (MIL-C-43892)
AD #: N/A
1 May 1974
Military specification for protective clothing is detailed in this letter
report.
3. Objectives and Systems for Decontaminating in the Field
Robert L. Bryant
AD-515894
28 June 1971
This document presents hazards (CBR) for each class item that night become
contaminated (skin, equipment, terrain) and possibilities for reducing these
hazards. Advantages and disadvantages, as well as characteristics, of present
and forecast candidate systems for decontiminating are discussed and the
systems are ranked according to effectiveness. Objectives and systems for
decontaminating each item are determined and summarized. Qualitative
relationships form the basis. for most of the analysis in the study. The scope
includes decontamination within the Army field area but excludes the items of
food, water, and explosive ordnance.
4. Research and Feasibility Studies on Clothing and Decontamination
G. L. Baude
AD-876647
11 September 1970
Studies on decontamination and percutaneous protection against chemical agents
were conducted by the Research Division of Grace and its Dewey & Army Division
and under subcontract by Monsanto Research, Molpar, Inc., and the Robinette
Research Laboratory. New or improved chemical agent decontaminants were
investigated: with selected metals, salts and compounds, phenols, and plastic-
ized ion exchange resins shýjwing the most promise. Attempts to catalytically
decontaminate agents by free radical initiated oxidation were not successful.
Silicones and silarances were also not effective.
51)L
Theoretical and experimentel variables were correlated for predicting the
performance of fabric impregnants as vapor barriers. The interaction between
fabrics or solid sorbent and liquid chemical agents were defined.
5. Personnel Decontamination Station
Arthur K. Stuempfle, Joel Klein, and Bernard V. Gerber
AD-B041888L
September 1979
This document describes procedures for personnel decontamination:
* General procedures for personnel decontamination in a controlled
station
* Problems which are required to be improved during the
decontamination process
0 Several questions and knowledge gaps
* Some decontaminant test data.
6. Investigation of Techniques for Decontaminating Personnel Protection
Items
K. J. Williams, J. J. Reidy, G R. Riley, C. V. Robinson, and D. A.
Easter
AD-B073613L
December 1982
As a result of concept discussion sessions and a literature survey, 11
decontamination techniques were selected for testing in this project:
conventional oven, infrared, vehicle exhaust, microwave radiation, vacuum
furnace, steam wand, steam cabinet, autoclave, ultrasonics, laundering, and
boiling. In laboratory tests designed to determine the physical effects of
each technique on various personnel protection items, samples of each item
were subjected to each decontamination technique. The samples were then
53
inspected for fading, staining, discoloration, and shrinkage, followed by
testing on a tensile-testing machine to determine the extent of tensile
strength loss caused by the particular technique.
Using the estimated damage criteria, the follcwing results were obtained:
conventional oven--all items but Nomex degraded; infrared--all items but Nomex
degraded; vehicle exhaust--all items but Nomex discolored or lost tensile
strength; microwave radiation--caused charring or melting of canvas, gloves,
webbing, boots, and overgarment foam: vacuum furnace--caused discoloration of
a number of items and caused a large loss in tensile strength of the gloves,
boots, and winter jacket liner; steam wand--caused least damage of any
technique; steam cabinet--stained butyl cloth, discolored webbing, faded
summer combat and canvas, shrank canvas, and caused a loss in tensile strength
in canvas and winter combat uniform liner; autoclave--faded cotton fatiques
and canvas, discolored butyl cloth and webbing, shrank overgarment foam and
webbing, and form liner; ultrasonics--faded butyl cloth, discolored Nomex and
canvas, shrank webbing, caused a loss of tensile strength in winter combat
uniform and butyl cloth; laundering--faded most fabrics, shrank canvas,
discolored overgarment foam and butyl cloth, caused stickiness in gloves,
shrank canvas, and caused a loss in tensile strength in the fatigues, canvas,
and winter combat uniform liner; boiling--faded the overgarment foam and
webbing, discolored the butyl cloth and the outer shell of the winter combat
jacket, shrank webbing and canvas, and caused a loss in tensile strength for
the canvas and fatigues.
7. Decontanination Methods for HD, GB, and VX--A literature Survey
Harvey W. Yurow
AD-BO57349L
April 1981
A literature survey was made, covering the period 1978-1981, for all ,_.thods
reported for the decontamination of the chemical warfare agents HD, GB, and
VX. Classes of chemical decontaminants described include strong L~ses,
complexing agents, nucleophiles and oxidants. Physical methods cited were
thermal and photochemial degradation and physical collection.
54
8. Chemical and Biological Warefare: Part II Protection,
Decontamination, and Disposal. 1978-1982 (Citations from the NTIS
Data Base).
AD #: N/A
May 1982
Government sponsored research is cited in the following four areas: agent
disposal by incineration, injection wells, ocean dumping, and chemical
deactivation; decontamination and removal of agents on equipment, on clothing,
in water, and from air including filtration and adsorption; collective
protection systems for buildings, shelters, and vehicles; ard protective
clothing. (This updated bibliography contains 101 citations, 47 of which are
new entries to the previous edition.)
9. Chemical and Biological Warefare: Part I Protection,
Decontamination, and Disposal. 1964-1978 (Citations from the NTIS
Data Base).
AD #: N/A
January 1981
This bibliography contains citations in the following four areas: agent
disposal by incineration, injection wells, ocean dumping, and chemical
deactivation; decontamination and removal of agents on equipment, on clothing,
in water, and from air including filtration and adsorption; collective
protection systems for buildings, shelters, and vehicles, and protective
clothing. (This updated bibliography contains 256 citations, none of which
are new entries to the previous edition.)
10. Chemical Decontamination ot Military Equipment Using Infrared Rays
Captain Mikho Penkov
AD-B026239
17 April 1978
The feasibility of using infrared rays for agent decontamination of military
equipment is discussed.
55
Infrared radiation is a stream of electromagnetic radiation, which results
from the oscillatory and rotary motion of the atoms and molecule of matter at
a temperature above absolute zero. The infrared spectrum occupies the region
of radiation having a wavelength from 0.8 to 1000 4m, i.e., from the red
boundary of visible light to the shortwave portion of the millimeter band.
Therefore, infrared radiation has the properties of both visible light and
radio-frequency radiation, i.e., it changes direction during reflection and
refraction like visible light. At the same time, like radio waves, infrared
rays can pass through some materials that are opaque to visible light. The
thermal effect of infrared radiation can be used for simultaneous heating of
all layers to create better conditions for vaporization of the toxic chemical
agents.
The infrared decontamination method provides for high productivity, eliminates
manual labor, achieves more complete decontamination of all toxic chemical
agents, does not damage paint, and does not cause rusting, which in turn
eliminates the necessity for additional treatment of decontaminated objects.
The method uses a cheap, domestically produced, and readily accessible fuel.
It is apparent from all that has been said, that decontamination by means of
infrared rays is a promising method, and it deserves more thorough investiga-
tion and implementation.
11. Approaches to Decontamination or Disposal of Pesticides:
Photo~lerompo~i ti on
Jack R. Plimmer
AD #: N/A
1978
Photochemical destruction of organic pesticides has not achieved the status of
a technological process that is applicable on a large scale; indeed, its
potential for detoxication of wastes or rendering them more susceptible to
microbial degradation has been little explored. There is an important need to
develop more data on rates and efficiencies of photochemial reactions.
Without this basic data, there is little point in discussing the question of
56
installation design and calculation of operating costs. In this discussion,
some limiting factors and indicated areas where progress is desirable are
outlined below:
* How rapidly do photochemical reactions occur, and what are their
energy requirements?
* How can some of the limitations be overcome?
0 What products are formed in photochemical reactions of
pesticides?
* What is the cost?
12. Methods and Material for Personnel and Equipment Decontamination;
Final Report for Task No. 24 on Collective Protection Against CB
Agents; Book I--Unclassified Data. 1970.
R. A. Sturgill and R. M. Sanders
AD-883442
November 1970
Full scale CB pod entry studies were made with manikins in sateen, liner, and
carbon overgarment outfits. Manikins were challenged with (1) dimethyl hydro-
gen phosphite levels of 100, 500, and 1000 mg-min per m3 and (2) diisopropyl
hydrogen phosphite droplet level of 3000 mg per manikin. Challenge level,
pre-entry aeration time, and decontamination procedures were evaluated for
each outfit and for each contaminant level. Full-scale, simulated 8 agent
shelter entries, were made. Test personnel were challenged at 103 and 104 Sm
per cu ft. Conditions were evaluated for personnel challenge and pod-and-
personnel challenge. The effect of peracetic acid on biological simula-,ts Sm
and PI and chemical agents GB and VX was investigated. Hypochlorous acid,
chloroperacetic acid, thorium nitrate, and uranyl nitrate were used on GB and
VX and compared to DS-2 for effectiveness.
67
13. Sorbent Powders for Ci~emical Warfare Decontamination
Thomas B. Stanford
AD #: N/A
April 1982
A type of Fuller's Earth (Surrey Finest) mined in Great Britain has proven to
be effective for the adsorption uf CB agents. The objective of this study was
to identify domestically available sorbent powder substitutes for Surrey
Finest which are equally capable of CW agent absorption. In tests conducted
with 22 Fuller's Earth materials against liquid- and vapor-phase CB agents, it
was found that 20 Fuller's Earth materials exhibit better sorption properties
than Surrey Finest.
14. Survey of New Sorbents for Application to Protection Devices
Leonard A. Jonas and JaquelIne M. Eskow
AD-A022 354
March 1976
The purpose of the study was to update and bring to the forefront a survey of
sorbents for application to monitoring and detecting devices. Because of an
ever-increasing need for protection against contaminated airstreams, the
United States and the United Kingdom are conducting a literature search to
correlate past and present developments in the adsorbent field. Sorption is a
basic requirement for respiratory protection, protective clothing, collective
protection decontamination and detection, and monitoring of unpurified air.
This colaborative research would lead to effective and simpler forms of
chemical protection. Since gas adsorption remains the basic mechanism by
which protection against chemical agents is obtained for both collective and
individual items, a periodic survey of new sorbents is important. It has been
found that: (1) A large number of carbons are commercially available which
have internal surface areas that are greater than that of the standard
Pittsburgh carbon. These carbons could be used to provide significantly
increased protection against physically adsorbed chemical agents. (2) A large
number of macroreticular resins, ion-exchange resins, and catalysts have
properties which can cause chemical changes in agent vapors producing nontoxic
58
products. Consideration should be given to the proper use of such resins
and/or catalysts which, in combination with carbonaceous sorbents, could
provide optimal mixtures for overall protection against toxic agents.
15. Compounding Techniques for Absorbent Decontaminants
Dewey P. Parks
AD-893611
January 1972
The objective of the program was to develop decontaminating systems for
persistent chemical agents using micronized carbon. These systems must be
effective in absorbing chemical agents and designed to the following goals:
act rapidly over a wide temperature range; be non-toxic and remain stable; not
damage material and equipment on contact; and be easily and rapidly applied to
vehicular equipment, clothing, and ancillary equipment.
The method of study was to select key ingredients, i.e., activated carbons,
thixotropic agents, dispersants, pigments and sol vent/anti freeze, and
formulate a system containing a minimum of 25% active carbon. It should be
easily applied by spraying to a coverage of 4 mg/cm2 and remain stable (not
settle during static storage of at least two years). Key nmthods of
investigation included evaluation of mixing techniques; effects of various
thixotropes and dispersant on viscosities and stability; and the evaluation of
spray equipment for optimization of techniques as well as equipment. In
addition, studies were conducted whereby dry formulation of the same key
ingredients were formulated. These compounds were tested for uniformity,
adhesion to woven surfaces and effect coverages in the 4 mg/cm2 range.
The results of these studies show that formulations containing approximately
35% active carbon can be easily sprayed to the desired coverage and will
remain stable for the desired two year period. All of the program goals
outlined above were met or exceeded by this study. Results also show that dry
formulations can be prepared by a special screened milling process to give the
desired uniformity, color, and adhesion.
59
It is concluded that in selecting the optimum ingredients to prepare a stable,
sprayable thixotrope that will meet all of the Edgewood requirements, the
following materials have shown to be superior: coal, petroleum, coconut and
wood based activated carbons are suitable as agent absorbents, however, the
coal and petroleum-based appear slightly superior. Dispersants are effective
in lowing viscosities with the sodium salts of polymerized substituted benzoid
alkyl sulfonic acid being most effective. Color can be obtained with iron
oxide and one-half percent sodium chromate or sodium silicate to inhibit rust.
A homogenizer will produce uniform mixtures of the wet-system and a special
screen milling machine will prepare satisfactory dry formulations.
16. Chemical, Biological, and Radiological Decontamination.
Department of the US Army Technical Manual
AD #: N/A
November 1967
The chapter 2 of this document is concerned with chemical decontamination and
consists of three sections. Section I is an introduction and general
discussion of chemical decontamination. Section II is a discussion of the
decontaminants which may be used for decontamination of chemical agents, and
Section III describes the recommended method for decontaminating various
surfaces.
17. Proceedings of the International Symposium on Protection Against
Chemical Warfare Agents Held at Stockholm, Sweden on June 6-9, 1983
National Defense Research Institute ABC Research Department
AD #: N/A
Jur,. 1983
The report contains the Proceedings from The International Symposium of Protec-
tion Against Chemical Warfare Agents, which took place in Stockholm 6-9 June,
1983. The papers were presented during sessions entitled Detection, Medical
Protection, Respiratory Protection, Decontamination, Civil Defense, and
Collective Protection, and Miscellaneous.
60
For technical reasons, the deadline for submittance of manuscripts had to be
changed at a very late stage, and, therefore, only abstracts are available of
some papers. However, a supplement containing the remaining full papers was
published during autumn, of 1983.
18. History of Recearch and Development of the Chemial Warfare Service
through 1945: Decontamination of Chemical Agents. Part I
J. Mankowich, A. F. Butcosk, R. Robbins, W. B. Roberts, A. L. West,
and S. Love
AD-872030
June 1970
Decontamination as described in this monograph is limited almost completely to
methods and apparatus for the amelioration of personnel, terrain, structures,
clothing, equipment, vehicles, and vessels contaminated with mustard [H:bis-
(2-chloroethyl) sulfide]. In order of presentation and length, there is to be
found a survey of historical decontamination procedures, a discussion of
demustardization methods for the period from 1920 to the early 1940's, and a
dcscription of the evolution of apparatus for the implementation of these
m.thods. The military characteristics of 41 devices and two systems evolved
in the study of methods and materials for decontamination are presented.
Detailed consideration is given to the technical aspects of chemical agent
decontamination. Such factors include the nature of the reactions between
contaminants and decontaminants, the mechanism of detection reactions, and the
analyses, physical and chemical properties, and stability of the divers
decontaminants. A history of the development and design for each of the major
systems; pieces of apparatus and techniques; the interrelation between them;
and their- individual, sequential, and concerned application has been prepared
and included.
19. Detoxification of Pesticides Using Soluble or Immobilized Enzymes
D. M. Munnecke
AD #: N/A
1978
61
Systems employing microbial enzymes which have the capacity to degrade toxic
pesticides may constitute new technology for detoxification and disposal of
pesticides. This paper reviews certain aspects of enzymatic degradation of
pesticides and discusses research concerning the utilization of cell-free or
immobilized enzymes in engineered systems for the industrial scale detoxifi-
cation of pesticides in waste waters, pesticide containers, or spray tank
rinse waters. A subject of environmental laws, methods of pesticide disposal,
microbial pesticide metabolism, cell-free enzymatic pesticide degradaticV, and
industrial enzyme application have been briefly discussed.
20. Engineering and Development Support of General Decon Technology for
the U.S. Army's Installation Restoration Program Task 5. Facility
Decontami nati on
William E. Jones, Janet Mahannah, Suzette Sommerer, and Judith F.
Kitchens
AD-A117565
July 1982
This report presents a technical evaluation of current and potentially useful
methods for decontaminating facilities contaminated with explosives and chemi-
cal warfare agents. Several alternative methods were identified as applicable
to the problems depending on the contaminant and medium contaminated.
21. Survey of Decontamination Methods Related to Field Decontamination of
Vehicles and Materiel (Abridged)
Frank Block and George T. Davis
AD-B031659
October 1978
Basic and applied work on chemical agent decontamination are reviewed, particu-
larly regarding field decontamination problems. Application of some foreign
systems are discussed. Suggestions of promising avenues for improvemient are
provided in the conclusions.
62
22. Decontamination Field Expedients--Summary of Results
Author: N/A
AD-C021098
February 1980
Contamination levels of thickened agents can be effectively reduced on non-
porous surfaces within an operationally realistic time with the use of field
expedient materials (3 to 11 percent of the agent chalienge remaining
following decontamination).
The order of effectiveness for field expedient decontaminants against
thickened GD (TGD) on bare and alkyd-painted metals was JP-4 > diesel > 50/50
aqueous etheylene glycol > Dugway Proving Ground clay soil.
The order of effectiveness for field expedient decontaminants against
thickened HD (THD) on bare and alkyd-painted metals was JP-4 > diesel > DPG
clay soil > 50/50 aqueous ethylene glycol.
Field expedient decontamination and/or weathering may be , ... ,red in addition
to a cover for reducing contamination levels below the lowest reported
thre•hold dose referenced in this report for TGD
23. Military Chemistry and Chemical Agents
Department of the Army and the Air Force
AD #: (TM 3-215 or AFM355-7)
August 1956
Chapter 7 of this document discusses all types of decontaminants with emphasis
on their chemical reactions. The chemical reactions include oxidation, chlori-
nation, reduction, and hydrolysis. Chemicals used as decontaminants may be
either inorganic or organic compounds which contain chlorine readily available
for use as an oxidizing or chlorinating agent. Inorganic compounds include
bleach in various fo.-ms, calcium hypochlorite. and chlorine itself. They
decontaminate by oxidation and are used for large scale decontamination.
Organic compounds include the chloramides arid closely related compounds. They
63
decontaminate, in absence of moisture by chlorination, in presence of mois-
ture by oxidation. These compounds are usually dissolved in an organic
solvent such as carbon tetrachloride or acetylene tetrachloride; they are
expensive, however, and are used only for small scale operations such as for
destroying blister gas on equipment.
24. Toxic Substance Control: Decontamination Symposium
George G. l)utterson and Theodore M. Prociv
AD #: N/A
April 1980
This symposium, sponsored by the U.S. Army Chemical Systems Laboratory,
ARRADCOM, was held during April 22 through 24, 1980 in Columbus, Ohio. The
symposium includes four areas: detection (warning/alarms, identification, and
monitoring); contamination control (contamination avoidance and decontamina-
tion); physical protection (individual and collective); medical aspects
(prophylaxis and therapy).
25. Chemical Warfare Capabilities--Warsaw Pact Countries
J. Kenneth Crelling
AD-B041660
October 1979
This review assembles the unclassified information available on the chemical
warfare posture of the Warsaw Pact countries, primarily the Soviet Union.
Although chemical warfare agents were not used in World War II, new agents,
the G-type nerve agents, had ,een developed by the Germans and manufacturing
plants had been built. During Germany's collapse in 1944 and 1945, the
Soviets captured some of these facilities, and transported them to Russia, and
reportedly initiated production there.
From 1945 to the present, chemial warfare doctrine for Warsaw Pact countries
has also become well established. Although it is not known in detail, adequate
information exists to allow interpretation of potential offensive operations.
While the Soviets unquestionably have the technology and capability to manu-
facture all types of chemical warfare agents, information on their stockpiles
64
appears to be mostly speculative, and size estimates range from several times
to many times compared to stockpile ranges indicated for the United States.
Among the chemical agents in their inventory, the Soviets have hydrogen
cyanide, soman, thickened soman, and VR-55, the last believed by some authors
to be another designated for thickened soman.
A full gamut of protective chemical-biological-radiological material is
fielded by Warsaw Pact Armies, including protective masks and clothing and
various collective protection systems, chemical agent detector-alarms and
identification kits, individual decontamination kits, a wide variety of
portable and vehicle-mounted decontamination equipment, including rapid-
decontamination vehicles and personnel decontamination stations.
26. Environmental Temperature and the Percutaneous Absorption of A
Cholinesterase Inhibitor, VX
F. N. Craig, E. G. Cummings, and V. M. Sim
AD #: N/A
1977
S-(2-diisopropylaminoethyl) o-ethyl methylphosphonothioate (VX), an anti-
chloinesterase liquid of low volatility, was applied to the skin of 139 men at
environmental temperatures -180, 20, 189, or 460 C. The skin was decontami-
nated after 3 hr and the men spent the next 21 hr at about 270 C. The amcunt
of VX penetrating the skin was estimated from the inhibition of red blood cell
cholinesterase. The decimal fraction of the dose that penetrated in 3 hr
ranged from 0.04 at -180 C to 0.029 at 466 C for the forearm. Further increase
in cholinesterase inhibition after decontamination was evidence of a deposit
of VX in the skin. The amount of VX remaining in the skin after decontamina-
tion was greater in the forearm and less in the cheek at higher temperatures.
27. Exploratory Development of a System for the Decontamination of Combat
Vehicle Interiors
R. L. Brunel, D. C. Doerschuk, G. R. Riley, and C. V. Robinson
AD-B049679
June 1980
65
Battelle's Columbus Laboratories investigated several techniques for the
large-scale decontamination of combat vehicle interiors. Tests involving theremoval of the chemical agent simulant diethyl phthalate from a metal plate
were conducted with four techniques: hot airflow, steam application, wishing
with detergent, and adsorpticn/vacuuming ,ith diatomaceous earth and with
Dutch powder. Steam application and hot airflow were determined to be the
most effective of these techniques, and thus were tested on military vehicle
interiors.
"•S. Study of Reactive Materials for Development of New Protective
Clothing Concepts, A
Donald R. Cowsar, Danny H. Lewis, and Gary W. Whitehead
AD-A054877
January 1978
This report describes investigations of reactive materials suitable for
incorporation in or on fabrics for protection from percutaneous chemical
warfare agents. Microencapsulated forms of alkali metal hydroxides and
aliphatic amines were developed and found to be unsuitable for protection fromHD. Aqueous solutions of aliphatic amines containing 4-(N,N-dimethylamino)
pyridine were found to destroy GB on contact. Microcapsules comprising
granules of stabilized XXCC3 in ethyl cellulose walls were found to react
readily with HD. These microcapsules were bonded to 8-oz sateen fabric with
resin binders, and the permeation of HD vapor through the fabric was deter-
mined. At contamination densities of 2.4 mg/sq m the HD v..por penetration was
found to be 6 jg/sq cm. The treated fabrics were tested for stability toward
washing and ultraviolet irradiation, and no change in agent vapor penetration
was observed for either the washed samples or those subjected to irradiation
for the equivalent of 1800 hours of sunlight.
29. Continued Investigation of Surface-Active Displacemenrt Solutions/SADS
II Detoxification and Application Dat&
A. E. Meyer, C. K. Akers, and R. W. King
AD #: N/A
3 September 1982
66
Two tasks were conducted for the project: (1) identification and preliminary
survey of detoxification of chemical warfare agents; (2) decontaminant field
application factors.
Fourteen types of detoxicants were identified through the literature search.
However, when considering safety factors, only chloramine-T was chosen for
malathion destruction test. At a 10:1 molar ratio of chloramine-T: malathion
[chloramine-T was dissoslved in a surface active displacement solution
(SADS)J, a greater than 99% destruction of the malathion in test solutions was
observed at 5° C, 22° C, and 450 C. When chloramine-T-SADS was sprayed on
painted aluminum panels that had been contaminated with malathion, it caused
an average of 65% malathion destruction within 5 minutes.
it was recommended that a general application SADS spray unit includes a
medium pressure, positive displacement pumping system. The unit should be
made portable by incorporating a gasoline or diesel engine for power. The
system pressure should be variable from several hundred psi to approximately
300 psi for cleaning and decontaminating substrates of various size and
delicacy. An array of interchangeable nozzles used in conjunction with the
variable pressure system could provide liquid flow rates from approximately
one to ten gallons per minute. The high pressure/flow combination could be
used on large objects that are heavily laden with dirt and debris, while more
delicate surfaces will necessitate the use of lower pressure/flow combina-
tions. High pressure hose (1/4 to 1/2-inch internal diameter), incorporating
high pressure quicK connectors, should be used for easily extending or
breaking down the hose assembly. The handheld spray gun should be made of a
durable material to withstand harsh use; its internal parts should be
chemically resistant to the SADS components. Safety ,eatures such as a
trigger lock and a comfort-designed handle should be incorporated. A "weep
flow system" for low temperature freeze protection is also recommended.
30. Evaluation of Decontamination Formulations
Gary D. Sides, Edward B. Dismukes, and Ralph B. Spafford
Ad-A106385
July 1981
67
This report describes a research program that had as its central objective the
development of a new water-based decontamination formulation effective against
G-agents and mustard. Desired properties of the formulation included not only
the rapid destruction of the three types of agents but noncorrosiveness,
nontoxicity, economy with respect to consumption of chemical reagents, and
logistical acceptability. The results of this research showed that micellar
aldoximes (1-n-dodecyl-3-pyridinium/aldoximes salts) at a pH around 9.5 are
good reagents for the nucleophilic destruction of GD and VX, but the data
obtained in a parallel investigation by another contractor (INTERx Research
Corporation Contract DAAK11-77-C-0098) indicated that these aldoximes are
ineffective against mustard. A search for othr nucleophilic reagents to
detoxify mustards was unsuccessful. An evaluation of N-halo organic
compounds, first as oxidative reactants for mustard, was then initiated.
Ultimately, 3-N-bromo-4, 4-dimethyl-2-oxazolidinone in a buffer of approxi-
mately pH 9.5 was found to be the most promising compound evaluated. In a
solution containing the surfactant cetyltrimethylammonium chloride in suffi-
cient concentration to form micelles, this N-bromo compound was found to
destroy mustard, GD, and VX with high effectiveness. The optimum composition
of the decontamination formulation was not determined, but a test formulation
0.030 M in the N-bromo compound and 0.034 M in the surfactant yielded prom-
ising results. Although the N-bromo compound is an active halogen compound,
its oxidation potential is well below those of inorganic hypohalites, and its
corrosiveness is thus expected to be much less than that of aqueous bleach.
31. New Oxidants and Mechanisms of Oxidation
I. C. Popoff and R. Helitzer
AD-384208
June 1967
Agents HD, VX, BZ, GF and selected model compounds were permitted to react
with the gaseous oxidants perchloryl fluoride, dinitrogen tetroxide, chlorine
dioxide, and chlorine. VX and HD appeared to be susceptible to oxidant
attack; whereas, BZ, if attacked at all, could usually be at least partly
regenerated from salts formed in the process. GF was not attacked at all.
The oxidation products were partially identified. Cotton cloth swatches and
glass or metal surfaces contaminated with HD were decontaminated to a con-
68
siderable degree, when exposed for 60 min to sufficiently high concentrations
of the gaseous oxidants. Cotton cloth swatches and glass surfaces contami-
nated with VX were decontaminated to the extent of 65% and 69%, respectively,
when exposed for 30 min to perchlory fluoride. It was established that the
enzymatic method is superior to the chromatographic method for establishing
the degree of decontamination. Cloth swatches were not weakened by exposure
to perchloryl fluoride or chlorine dioxide, but were significantly attacked by
chlorine and dinitrogen tetroxide. Aluminum, stainless steel, magnesium,
Plexiglas II, and neoprene were attacked with varying degrees of severity by
gaseous oxidants on week-long exposures, especially at 50% (in contrast to 0%)
relative humidity; attack by perchloryl fluoride was in almost every instance
minimal. Thus, it would appear that perchloryl fluoride might be used to
decontaminate materials contaminated with HD (and perhaps VX) without
degrading the materials.
32. Decontamination of Surfaces Contaminated with Chemical Agents
Battelle Institute E. V. Frankfurt/Main
AD-B034759
July 1978
New P (V)-nucleophilic compounds were synthesized and subjected to a
standardized test program. Of the water soluable compounds investigated,
polyacrylamidoxime showed the highest reactivity with DFP. The product formed
by reaction of chloroacetylhydroxylamines with alkyldimethylamines showed very
good reactivity with DFP and paraoxon.
33. Phase I: A Feasibility Study on the Possible Development of Resin
Polymer for the Filtering and Sensing of Chemical Agents
Donald R. Owen and John Jacobus
AD #: N/A
15 February 1979
This document discusses the following items:
0 General biological and chemical properties of chemical warfare
agents
69
0 Review of polymeric chemicals and reactive polymeric materials
0 Reactive polymeric matrices for chemical warfare agent removal.
Two recommended approaches are mentioned: 1) active resin
system to have the capability of reacting directly with chemical
warfare agents; 2) active resin to catalytically hydrolyze war
agents to less toxic compounds. Several copper chelates are
proposed to be attached to polymeric substrates.
* Solid state agent detection systems
34. Study of Agent-Reactive Fabrics for Use in Protective Clothing, A
Gerald Zon
AD-A079940
December 1979
A broad investsigation has been carried out to obtain modified fabrics which
exhibit catalytic activity toward hydrolytic decomposition of chemical warfare
agents. The major areas of study included the development of chemically
modified Nomex and cotton-blend fabrics, mechanistic inquiries with regard to
factors which control simulant/agent hydrolysis, and the design and construc-
tion of a suitable fabric testing apparatus for comparative evaluation of
candidate fabrics.
35. Organophosphorus Pesticides: Organic and Biological Chemistry
Morifusa Eto
AD #: N/A
1974
In order to get a general concept of organophosphorus pesticides with such a
variety in structure and biological activities, consideration of each aspect
of chemnistry. biochemistry, and the applied sciences is necessary. This book
consists of these three main parts. After the presentation of the background
of phosphorus chemistry in Chapter I, stress was put on the chemical and
biochemical reactions of organophosphorus pesticides, includiiig synthesis,
analysis, metabolism mode of action, and other interesting aspects in
70
Chapter II to IV, and on the structure-pesticidal activity relationship in
Chapter V. Almost all commercialized and important experimental organo-
phosphorus pesticides are mentioned. Unlike insecticides, the mode of action
of other pesticides is not well established, and the scattered knowledge about
them is difficult to generalize. They are described in the corresponding
sections of Chapter V, "Individual Pesticides." Although this book is
designed as a readable text, it has reference value also.
36. Development of Package Decontaminating System (Final Report)
G. A. Richardson
AD-906245L
August 1972
The highly complex chemistry of DS-2 has been reasonable well resolved during
this research program. This was essentially accomplished by (1) theoretically
defining the primary function and/or functions of each of its components
through mechanistic organic chemical theory and (2) by designed experiments
which would either nullify or verify those theories.
The primary function and/or functions of each of the components in DS-2 are as
follows: (1) diethylenetriamine serves as a strong chelating agent for the
sodium ions; (2) methyl cellosolve serves as an extender for the amine, base
and agent; in addition, it contributes to the formation of sodium
2-methoxyethoxide; (3) sodium hydroxide also contributes to the formation of
sodium 2-methoxyethoxide which is the primary decontaminant in DS-2. Further,
and of the utmost importance, diethylenetriamine and methyl cellosolve combine
in a specific ratio to form an azeotropic mixture.
An attempt was made to improve DS-2's decontamination integrity (i.e., faster,
ease of application, and less corrosive, etc.) by modifying the DS-2
forrulation, but none of the substitute formulations was found to be markedly
superior to DS-2.
71
37. Studies on the Destruction of Toxic Agents VX and HD by the
All-Purpose Decontaminants DS-2 and CD-1
George T. Davis, Frank Block, Harold Z. Sommer, and Joseph Epstein
AD #: AD-AO09708
May 1975
Kinetic evaluations were conducted of the efficiency of decontamination of
agents HD [mustard:bis(-2-chloroethyl) sulfide] and VX [0-ethyl S-(diisopropyl-
aminoethyl) methylphosphonothiolate] by the Army all-purpose decontaminant,
DS-2 and the Air Force all-purpose decontaminant, CD-I. Some of the products
have been isolated or identified. Spectrophotometric yields of the major
product from HD decomposition by these decontaminants have been obtained.
38. Examination of Macrocyclic Ether-Alkali Metal Salt Complexes as
Decontaminants for Chemical Warfare Agents in Non-Aqueous Solvents, An
ý. A. Casselman, H. Gail Thompson, and R. A. B. Bannard
AD-A077516
October 1979
The feasibility of using macrocyclic ether--alkali metal salt complexes to
effect the rapid destruction of the chemical warfare (CW) agents HD, GF, and
VX at or near room temperature, in non-aqueous solvents has been examined. An
investigation of the decontamination efficiency of complexes formed by the
macrocyclic ethers, 15-crown-5, 18-crown-6 and cryptand [2.2.2] in conjunction
with inorganic salts such as alkali hydroxides, potassium superoxide,
potassium tert-butoxide, potassium dichromate and potassium acetate has been
made. Agent destruction levels exceeding 80% were effected within 2 to 5
minutes at room temperature by several of the systems examined. Cryptand
[2.2.2] was the most effective of the macrocyclic ethers in facilitating agent
destruction. Generally, the relative ease of destruction of agents by the
macrocyclic compounds followed the order HD > VX > GF. It is concluded that
this new general approach to chemical decontamination is sufficiently
promising to warrant further study by extension to other nucleophiles and
cations.
72
39. Brief Review of the Chemistry of Crown Ethers, A
R.A.B. Bannard and A. A. Casselman
AD #: N/A
April 1976
This document briefly describes the following parameters of crown ethers.
4 History
* Nomenclature
* Formation and stability of crown ether-metal ion complex
* Research and Application
* Physiological Property
* Synthesis method and isolation
* Analytical characters
0 References
73
APPENDIX B
INDUSTRY TELEPHONE INQUIRIES
POLYMER SEARCH
Company Address Phone
American Cyanamid Wayne, NJ (201) 831-2000
American Polymers, Inc. Patterson, NJ (201) 697-1880
Amoco Chemical Corp. Chicago, IL (312) 856-3528
B. F. Goodrich Cleveland, OH (216) 447-6000
Cadillac Plastics and Chemical Co. Birmingham, MI (800) 521-4004
Casden Oil and Chemical Dallas, TX (214) 750-2800
Chemical Coating and Engineering Co. Media, PA (215) 566-7470
Dow Chemical Co. Midland, MI (800) 248-2345
Dupont De Nemours Wilmington, DE (302) 774-2421
Fiberfil Division Evansville, IA (812) 424-3831
H. B. Fuller Co. St. Paul, MN (800) 328-9673
Hercules, Inc. Wilmington, DE (302) 594-5000
Lab Safety Supply Janesville, MI (800) 356-0783
Minnesota Mining & Mfg. Corp. 3M Center St. Paul, MN (612) 733-0306
Minnesota Mining Mfg. Reg. Technical Rep. Atlanta, GA (404) 447-7132
Olin Corp. Chemical Division Stamford, CT (203) 356-2525
P. P. G. Industrial, Inc. Pittsburgh, PA (412) 434-2583
R. A. Chemical Corp. New York, NY (212) 859-2800
Richardson Technological Services Madison, CT (203) 245-0441
Rohm and Haas Co. Philadelphia, PA (215) 641-7000
Saltamer Co. Westchester, PA (215) 692-8400
Shell Chemical Co. Houston, TX (713) 241-6161
U. S. I. Chemicals Dallas, TX (214) 387-1130
Union Carbide Atlanta, GA (404) 633-6161
Uniroyal Chemical Co. Naugatuck, CT (203) 723-3849
Universal, Inc. Kensington, CT (203) 828-0335
Upjohn Polymer and Chemical Division La Porte, TX (713) 979-1541
Westlake Plastics Co. Lenni, PA (215) 459-1000
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ADHESIVE SEARCH
Company Address Phone
Adell Plastics, i,,L. Baltimore, MD (301) 789-7780
Allied Chemical Corp. Morristown, NJ (201) 455-2483
American Cyanamid Wayne, NJ (201) 831-2000
American Polymers, Inc. Paterson, NJ (201) 697-1880
Argus Co. Brooklyn, NY (212) 858-5678
Dow Chemical Co. Midland, MI (800) 248-2345
Dupont De Nemours Wilmington, DE (302) 774-2421
Durey Division ot Hooker Chemicals New York, NY (716) 696-6234
Eastman Chemical Products Kingsport, TN (615) 247-0411
Emerson and Cuming Canton, MA (617) 828-3300
Fiberfil Division Evansville, IA (812) 424-3831
FMC Corp. Princeton, NJ (609) 452-2300
H. B. Fuller Co. St. Paul, NM (800) 328-9673
Hercules, Inc. Wilmington, DE (302) 594-5000
Montedison USA, Inc. New York, NY (212) 764-0260
Olin Corp. Chemical Division Stamford, CT (203) 356-2525
P. D. George Co. St. Louis, MO (314) 621-5700
P. P. G. Industrial, Inc. Pittsburg, PA (412) 434-2583
R. A. Chemical Corp. New York, NY (212) 859-2800
Rohm and Haas Co. Philadelphia, PA (215) 641-7000
Saltamer Co. Westchester, PA (225) 692-8400
3M Corp. 3M Center St. Paul NM (612) 733-0306
3M Regional Technical Rep. Atlanta, GA (404) 447-7132
Union Carbide Atlanta, GA (404) 633-6161
Universal Inc. Kensington, CT (203) 828-0335
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